DE29819222U1 - Deep sea power plant - Google Patents

Description

The subject of the invention is a

" Deep sea power plant " to generate electricity

Power plants for generating electricity are known in many variations.

The most common method for over 100 years has been the use of hydropower, whereby the pressure of water in turbines is used to drive power generators in rotating energy. In order to be able to exert ever higher pressures on the turbines, water was also converted into steam using additional energy.

Every usable force, whether wind, muscle or tidal power, has so far been used to generate electricity.

Nuclear fission or nuclear fusion, also known as nuclear power, has been used to generate electricity for around 50 years. However, this power is unpredictable and extremely dangerous because, for example, the ash produced is highly toxic for future generations.

In addition, in the event of a so-called super-GAU in a densely populated area such as Germany, an entire population is condemned to extinction due to the radioactivity released. The soil contaminated in this way will also no longer be usable by humans for many thousands of years.

To avoid these disadvantages, the inventor proposes an ^11" deep-sea power plant ". It consists of welded steel plates, comparable to conventional large shipping containers, with variable dimensions.

As an example, a rectangular steel container 50 meters wide and high and 300 meters long is to be prefabricated in a harbor basin so that during the construction period it can be further manufactured by tugboats in its remaining location in deeper water of about 70 meters until the final cubic body is welded together.

The first construction phase begins with drilling holes in the seabed about 50 to 100 meters deep in a row parallel to the surf. Anchors are inserted into these holes, which have a chain eyelet at the top. In parallel, the same number of holes with corresponding anchor eyes are also drilled at intervals of 200 meters.

After a floating container prefabricated in the port has been assembled to a sufficient depth of water, it is pulled into deeper waters by tugboats.

However, before this container is towed, a half-tunnel must be installed longitudinally at its bottom.

Large turbines and work equipment are arranged in this half-tunnel.

In the middle of the half-tunnel, a square shaft is installed so that an elevator can be installed in it later.

Half-shell-shaped sheets of metal are also welded around the floating container, which, once completed, each represent a floating container, giving it the character of a Triomaran.

This container, which has been formed in this way, is now towed to its final location and secured to the previously installed anchors using thick chains.

A valve is arranged in the half-tunnel so that when it is opened, seawater can flow into the interior of the tank through the turbine and a pipe connection that penetrates the tunnel. A floating raft floor is now attached to the inner water surface, which the work personnel use to assemble additional tank walls and the associated reinforcements. As the tank walls are raised further, seawater is fed through the valve through the turbine into the interior of the tank, with the raft floor always adjusting to the working height. After the floating steel tank has reached its final height of 50 meters, another metal floor is welded in as a watertight closing surface. Before this, the floating raft floor is removed step by step. This creates a platform made of sheet steel that is 50 meters wide and 300 meters long.

After that, another 10 meters of tank walls are added as a rehiing in an inclined position. Self-closing flaps are arranged in this inclined position. Then a second platform, also 50 m * 300 m, is introduced in such a way that a gap of about 3 meters is created and the platform, as the final upper deck, protects it from wind and waves. In the middle of the platform, a rectangular tower of about 20 meters is erected. The elevator is located in this tower, which penetrates the tunnel below and is welded tightly. The compressor and air pressure tank are located in this tunnel. There are funnels on the upper deck and flaps on the surf side that open when the pressure of an approaching water wave presses against the side planks. These flaps close automatically due to their own weight. The inflowing water is fed to the tank floor via the funnels. However, these funnels must be closed with throttle valves in the intermediate deck.

After the completed " deep sea power plant " has reached its final water depth and is only 5-10 meters above the sea floor, the anchor chains hang down from the deep sea power plant on the sea floor. Now all the flooded air tanks around the deep sea power plant are filled with air using a compressor, whereby the water is pushed back into the sea through a valve. The valves are then closed and the deep sea power plant increases its distance from the sea floor using buoyancy.

A valve is then opened that is installed in a pipe leading to the turbine. An outflow pipe from the turbine leads to the open sea.

Now air pressure is pressed between the water level inside the deep-sea power plant and the ground, so that the water masses are pressed through the opened valve, through the turbine and the drain pipe below sea level. After the entire amount of water has been pressed out of the hull of the deep-sea power plant, the valve is closed again and the entire deep-sea power plant is only held in place by the anchor chains. The deep-sea power plant now protrudes from the water surface at the desired height, attached only to the chains. If the anchor chains were now released, the entire deep-sea power plant would protrude a further 25 meters from the water surface. However, this buoyancy force is intentional, because if the valve that supplies the first turbine with water is now opened, sea water will flow into the hull of the deep-sea power plant at high pressure. Seawater flows through the turbine under pressure and drives the generator to generate electricity until the hull of the deep-sea power plant is about 60% full. The air inside the container is compressed. A limit switch switches off the valve to the first turbine as soon as a certain water level is reached.

Then a second valve opens, which passes through the inner tunnel

feeds a second turbine with water.

The compressed air above and the buoyancy forces

push or suck the water in the hull through the

Drainage pipe at sea level, whereby the

second turbine by the force of lift and the compressed air its rotational movement to the generator to generate electricity.

(Immediately in or above the generator

Compressed air injected) This happens alternately, so that current is constantly

is produced, both at full and reduced load.

In very rough seas, the hull of the It can also be filled by switching off the limit switch and shutting off the valves so much water

that sinking to the seabed is possible.

During this phase, the power plant can continue its work under certain conditions

Only the tower of the elevator would be above the

sea level, sometimes 10, sometimes 20 meters high. So that the

The generator sucks the water column above it faster to the surface water and thus the turbine gives more power, is immediately before the

Generator injected with compressed air. This air-water mixture reaches the surface more quickly. As soon as the sea is calmer, air is again pumped between water level and the separating floor, and the The work can again be carried out in the upper area.

The invention of the deep-sea power plant will now be described in more detail using a schematic representation:

Figure T shows the deep sea power plant in

Section from the side, with all chambers filled with air anchored to anchor chains in the seabed, so that these anchor chains have a tensile load of about 25 meters of water column pulling the steel container below sea level.

Figure 2 shows the deep-sea power plant in

in section also in side view, but the deep-sea power plant is filled with seawater from the inside and the compression chamber is exposed to air pressure.

The deep-sea power plant consists of a steel container (No. 1). Half shells (No. 2) are arranged around the steel container (No. 1). A tunnel (No. 3) is welded onto the inner floor of the steel container (No. 1) in such a way that a sealed, half-tunnel-shaped tube (No. 3) is created, which forms an independent pressure chamber independent of the entire steel body (No. 1). In the upper area of the steel container (No. 1) another air chamber (No. 4) is created by the dividing floor (No. 5) and the platform (No. 6). An elevator shaft (No. 7) is arranged centrally in the hull of the steel container (No. 1) in such a way that it cuts through the tunnel tube (No. 3) on the floor and thus makes the tunnel accessible.

Turbines (No.8 and No.9) are installed in the tunnel (No.3). One turbine (No.8) is connected to the turbine by a pipe (No. 10) Steel container (No. 1) severed, connected. A valve (No.11) seals the pipe (No.10). A standpipe (No. 12) serves as a drain and float switch. The other turbine (No.9) has an inlet pipe (No. 13),

which penetrates the tunnel tube (No.3) and in the interior of the

steel container (No. 1) ends. In the drain pipe (No. 14), which slides to the sea level

There is a shut-off valve (No. 15) in the pipe.

Associated with the steel container (No. 1) are anchor chains (No. 16),

which are anchored in deep borehole anchors (No. 17) with

Anchor eyes (No. 18 and No. 19) are anchored. The steel container (No. 1) is surrounded by Half shells (No.2) are connected to a compressed air line (No.20) via

a compressor (No.21).

At the lower end of the half shells (No.2) there is a valve (No.22). Around the platform (No.6) there is a Railing (No.23) is attached. In this railing (No.23) are on the Pendulum flaps (No.24) are installed on the surf side. Pendulum flaps (No.24) can capture surf waves

They close as soon as the wave pressure has subsided. The higher water level is fed via the funnels (No.27) to the

Steel container bottom (No. 1). For mounting the steel container (No. 1) an internal Raft bottom (No.25) stored. The steel body thus manufactured (No. 1) with the corresponding

installed devices and fittings, the

deep sea power plant. In order to start work, Using the compressor (No.21) the water is pumped out of the Half shells (No.2) pressed out over the valves (No.22). Then the valve (No. 22) is closed. Then the steel container (No. 1) is filled between the inner

lying water surface and the separating floor (No.5) with the help of the

Compressor (No.21) pumped air so that this gap

as compression chamber (No.26) completely over the now opened valve (No. 15) through the drain line (No. 14) is discharged into the open sea.

As soon as the compression chamber (No.26) is Inlet pipe (No.13) is free of water, the Valve (No. 15) is closed and the entire Steel container (No. 1) is buoyed by the air chambers,

which causes very strong tensile stresses on the anchor chains (No. 16) and the installed drill anchors (No. 17 and No. 18) This will be about half buoyant and out of the water The towering steel container (No. 1) represents the deep-sea power plant.

So that the turbine (No.8) can now be driven,

the valve (No. 11) is opened and a water column of about 50 meters drives the turbine (No.8) until the

Steel container (No.1), filled to about 60%, the limit switch (No.12)

is activated and the valve (No. 11) closes again.

In interaction, the valve (No. 15) is now opened,

and the compressed air from the compression chamber (No.26) as well as the tensile forces from the half shells (No.2) allow the existing water via the inlet pipe (No.13), the turbine (No.9) and the drain pipe (No. 14) flows into the open sea.

The buoyancy forces and the compression pressure are thus

the turbines (No.9) and corresponding power generators in converted into electrical energy.

This way of working always happens in interaction,

The deep-sea power plant can also be controlled in such a way that most energy is produced during peak times.

Once the deep-sea power plant has reached its deepest point,

upcoming water waves on the surf side

Open and close flaps and apply higher water pressure to

the inlet pipe (No. 13).

In very heavy seas, the deep-sea power plant can also be placed on the bottom so that only the elevator shaft (No. 7) protrudes from the surf, and in this case the air chamber (No. 4) provides additional buoyancy when resurfacing.

The valves (No. 28) are closed.

The angles on the steel tank bottom (No. 1) can be used as air pressure chambers (No. 29) by welding a sheet of metal at the top and bottom. All air chambers are filled with compressed air during periods of low power so that there is always enough air to inoculate the turbine (No. 9).

The escaping water-air mixture is an area for the seas. The seabed (No. 31) and the sea level (No. 30) must be selected in such a way that the elevator shaft (No. 7) protrudes even during high storm surges so that the compressor (No. 21) receives sufficient air supply.

Claims (1)

Utility model claims Utility model claim 1 characterized in that half shafts (No. 2) are arranged all around a steel container (No. 1), and that in this steel container (No. 1) a tunnel tube (No. 3) is arranged on the steel container floor (No. 1) in such a way that this tunnel tube (No. 3) can be accessed centrally through the steel container (No. 1) and an intermediate space (No. 4) from an elevator in the shaft (No. 7). Utility model claim 2 characterized in that in the seabed parallel to the steel container (No. 1) there are anchor holes (No. 18 and Wr. 19) about 30-50 m deep, which at the deepest point engage anchor hooks in the ground. Utility model claim 3 characterized in that in the Tunnel tube (No.3) turbines (No.8 and 9) and a valve (No.11) are arranged. These valves (No. 11 and 15) only have the task of confirming the inlet pipe (No. 13) and the drain pipe (No. 14). Utility model claim
4 characterized in that in the Self-closing valve flaps (No. 24) are installed in the railing wall (No. 23), and that the water masses are fed to the bottom of the tank via a funnel (No. 27) and the higher water column increases the compression pressure on the inlet pipe (No. 13). The inlet pipe (No. 27) can be secured by valves (No. 28).