DE102008047244A1 - Apparatus and method for using hydrostatic energy - Google Patents

Abstract

The invention relates to an apparatus and a method for using hydrostatic energy. The invention provides: two chambers one above the other, water chamber in the core of a tall building (skyscraper); Height of the water chamber corresponding to the building minus 2 floors; that the power usage units are composed of pipe segments; that the water chamber is filled to about 9/10 with water; that the upper chamber contains the water turbines, the flywheels and the generators; in order to stabilize the walls in the water chamber and to guide the lowering pipes cross-braced struts are provided at a uniform distance up to the total height of the building.

Description

Description according to claim 26:

Claim 26 is intended for power generation in a tall building (skyscraper). The water chamber is located in the core of the building ( 1 , Side view) The system consists of two chambers one above the other, the lower chamber corresponds to the building height minus 1 to 2 floors. The lower chamber, bsw. 25 m ² area ( 2 No. 1 ) includes the force utilization units ( 1 No. 3 or 2 No. 2 , View from above) after the piston principle with hopper trough and riser, which are composed of individual pipe segments. The upper chamber contains the riser and the water turbine ( 1 No. 4 and 3 No. 6 ) for generating the rotational force. The torque is generated by means of a turbine shaft ( 3 No. 3 ) to a flywheel and dynamo passed into a separate chamber. The water outlet is behind the turbine in each case in the next chamber ( 3 No. 4 ). Then the water flows through holes in the upper chamber ( 3 No. 2 ) back to the lower chamber. The lower chamber is filled to about 9/10 with water; the wall thickness of the water chamber must be built according to the water pressure. For thinner walls ( 2 No. 3 ), cross straps can stabilize the walls as well as provide stability for the drain tubes ( 2 No. 4 ). The upper chamber consists of at least two or more separate chambers, 3 No. 5 ). The power generation by flywheel and generator takes place on the top floor at the level of the upper chamber, but in a separate chamber next to it. The flaps are moved by electronic control and hydraulics.

Description according to claim 27:

Claim 27 is intended as an industrial building for use as a hydrostatic power plant for energy production. The dimensions can bsw. Length 81 m, width 51 m, height 120 m ( 4 , Overall view page and 5 , Overall view above). These diagrams show 5 rows a '5 chambers for the power units ( 4 No. 1 and 5 No. 1 ) with the water turbines in that chamber and the common turbine shaft ( 4 No. 2 . 5 No. 2 and 6 No. 1 and 2 ) and energy production ( 4 No. 5 and 5 No. 4 ) The building consists of two chambers on top of each other ( 4 ). In the lower chamber are the power units with hopper trough housed ( 4 No. 1 ). These power units are made of pipe segments ( 4 No. 7 ). In order to reduce the water pressure on the outer walls, the building is divided into individual buoyancy chambers ( 5 No. 1 ). Cross-strapped brackets can stabilize both the walls of the chambers and the tubes ( 7 No. 1 ). The size of the plant and the number of power units can be arbitrary, it must be ensured only enough buoyancy force in each of the self-contained water chambers. In the upper chamber are each the riser pipes, which open into the water turbines ( 4 No. 2 ), corresponding to the number of power units in the lower chamber. The water behind the turbines flows back into the upper chamber ( 6 No. 3 ) and then through holes in the lower chamber ( 6 No. 4 The turbines in the upper chamber form a torque for a flywheel on a common shaft ( 4 No. 3 and 5 No. 3 ) in an extra chamber at the same level, which stores the absorbed power of the water turbines and continuously emits. When reaching the desired speed is by means of a coupling ( 4 No. 4 ) the dynamo is connected to the electricity generation ( 4 No. 5 ). The floors below are intended for other power stations ( 4 No. 6 ) The flaps are moved by electronic control and hydraulics.

Description according to claim 28:

Instead of - or in addition to - one Rubber seal at the bottom of a container or a bottom plate at the bottom of a clear water can Absenkrohr to its bottom a rubber seal according to the pipe shape to shield the water pressure outside the pipe.

Description according to claim 29:

The invention according to claim 29 is intended for facilities where frequent shortening or extension of the tubes of the power units is necessary, bsw. on ships. The system consists of several, nested tubes ( 8th No. 2 ). The lowering tube is shown in the figure round, but it can also have any other shape. In the upper chamber, roller-mounted and electrically driven steel cables ( 8th No. 1 ), the lowering tubes can move up and down. The steel cables have internally insulated, electrical cables for the electrical control of the flaps ( 8th No. 4 ) at the lowest lowering tube segment. In this embodiment, the smallest segment (of diameter) is firmly attached to the funnel trough of the upper chamber. For systems according to the bellows principle, the bellows may thus only have the diameter of the smallest tube. The largest tube has on its underside an inwardly directed wide flange ( 8th No. 3 ) to hold up the smaller pipe segments when pulling up. The control of the valves of the upper chamber and the Absenktroges are electronically gesteu ert.

Description according to claim 30:

The invention according to claim 30 is similar to that of claim 29, only with the difference that here the largest Absenkrohr segment is attached to the funnel trough of the upper chamber ( 9 ). The advantage here is that each Absenkrohr segment be, from the diameter ago matching bellows segment has ( 10 No. 1 ). In order to prevent a nesting of the smaller into a larger bellows segment, a reinforcing grid is located on the lowest side inside each bellows segment ( 10 No. 2 and 11 ), which prevents this. This grid is made of plastic or aluminum and is firmly connected to the bellows.

Description according to claim 31:

The invention according to claim 31 are provided as a particularly space-saving, but effective large power plants. They consist of a large water tank ( 12 No. 1 ) inside the building. To stabilize the walls of this water tank, braces ( 12 No. 5 ) inside the tank at a distance of bsw. 10 m to the total height of the structure introduced. Around this water tank are the actual force utilization chambers ( 12 No. 2 ) built. The whole is then completed by a second outer wall ( 12 No. 4 ) Only above the power utility chambers (outside the water tank) is there another floor in which the chambers with water turbines and riser pipes ( 13 No. 3 , Flywheels ( 13 No. 4 ) and generators ( 13 No. 1 ) are. On the inside of the water chamber, bulkheads are fitted to the force-utilization chambers to shield the water pressure. Such a bulkhead can be vertical ( 14 No. 1 + 2 ) or horizontally ( 14 No. 3 + 4 ) are opened and closed electronically controlled. The free floors under the generators can be used for other power plant facilities.

Description according to claim 32:

The Invention according to claim 31 is also particularly suitable for space-saving Energy generation as a heating system. The plant stands with the dimension of bsw. 2 m length × 2 m width × 2 m height on the Floor space a former fuel oil tank. For the However, power generation is particularly well priced here Plant according to the bellows principle. The free spaces under the small generators can a) for the generation and storage of hydrogen (for later combustion as oxyhydrogen flame) or b) to accommodate heating elements with Coils (similar to a water heater) and the insulated Storage of hot water can be used.

Description according to claim 33:

For systems with a very long bellows it is necessary to reinforce the bellows against undesired deformations. These are in the large folds of the bellows ( 16 No. 1 ) Reinforcing grid ( 15 ) with very low weight (eg made of plastic or aluminum) This grid is firmly connected inside the bellows with every large folding.

Description according to claim 34:

For systems with extendable lowering tube ( 8th ) is provided for use according to the piston principle, a special piston. This piston has in addition to the inner solid on the sides of the lowering tube movable bellows blades made of rubber or soft plastic. Without air in the piston, these slats contract due to their own momentum. Thus, the piston can fall due to its gravity in the water-filled pipe. If the piston is filled with air at the lowest end of the pipe, these fins expand and are pressed against the pipe wall. However, the injected air into the piston must be such that the pressure is not too strong even in the smallest pipe against the pipe wall, so that, if necessary, the buoyancy is hindered. If the piston comes in buoyancy in a next smaller tube, the lamellae are further compressed. At the top of the topmost tube, the air from the piston is released into the funnel trough. It should be noted, however, that the inner transition from tube to tube is tapered so that the piston does not stick to the tube junctions. So that these conical tips are not damaged in the interior of the tube when retracting the lowering tube, the individual tube segments have at the upper end a flange through which a gap remains when retracting the tubes. This piston is also suitable for drain pipes ( 9 + 10 ), in which the largest lowering tube is not at the bottom, but at the top of the funnel trough. Where are the bellows blades at the lowering tube after 8th in the direction of the funnel trough, they expand in the lowering tube 9 + 10 out.

Description according to claim 35:

A system according to claim 35 is intended for water or other fluid promotion. Two pools (artificial or natural) at different altitudes are required ( 17 No. 1 + 2 ). One or more drain pipes ( 17 No. 3 ) according to the piston principle are on a support structure ( 17 No. 4 ) attached. The upper chamber contains water turbine, Elek trik, dynamo and compressed air system ( 17 No. 5 ). The water of the lower level is through the piston in the lowering tube through the riser ( 17 No. 6 ) pumped into the upper level basin. Small plants could be used to irrigate higher areas. But it can also be a power generation by pressurized water turbines, driven by the water of the upper to lower level done. Here, the water, unlike reservoirs is not lost, but is passed through the system according to claim 35 back into the upper pool. If the lower water level is clean seawater, appropriate installations can also be used to desalinate seawater for the production of drinking water or industrial water (eg for plants).

Description according to claim 36:

Systems for using hydrostatic energy according to claim 36 are mounted on ships. The attachment of the upper chambers is made so that they protrude beyond the ship's wall, so that the lowering tubes mounted under the chambers can be extended into the water. For this, the extendable and retractable lowering tubes of claims 29 and 30 are used ( 19 No. 1 ) Retracted, the drain pipes do not touch the water surface. In the upper chambers are the funnel troughs with riser and water turbine ( 19 No. 2 ) housed. The generators needed to generate electricity are located behind it on the ship's deck and are connected to the water turbines each through a turbine shaft. The drainpipes have an oval or diamond shape, the narrow side in the direction of travel of the ship. The electricity generated is used for a seawater desalination plant located on the ship. The ship can move towards a disaster area and simultaneously prepare seawater for drinking water and store it in tanks in the belly of the ship. Carbon dioxide can be added to the drinking water for preservation. If necessary, the drinking water can also be filled on board in canisters or bottles. The water can then be quickly brought to the affected by on-board electric amphibious vehicles. For these vehicles are at the stern of the ship up and down ramps.

Description according to claim 37:

In order to avoid negative effects on the drainage pipes due to current and swell, the retaining structure ( 20 No. 1 ) in a free waters struts ( 20 No. 2 ) evenly spaced to the bottom of the body of water securing the lowering tubes.

Claims (12)

Claim 26: Apparatus and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 12, 13, 14, 20, 21, 23, additionally characterized : - two chambers one above the other - water chamber in the core of a high building (skyscraper) - height of the water chamber, corresponding to the building minus 2 floors - the power units are composed of pipe segments - water chamber to about 9/10 filled with water - the upper chamber contains the water turbines, the flywheels and the generators - Zur Stabilization of the walls in the water chamber and to guide the lowering tubes are cross-braced struts evenly spaced up to the total height of the building Claim 27: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 12, 13, 14, 20, 21, 23, additionally characterized - Building with 2 chambers on top of each other - Building divided into smaller chambers to relieve the external walls - the upper Chamber includes the water turbines, the flywheels and the generators - the Power utilization units are composed of pipe segments - For stabilization of the chambers and to the leadership of the Lowering tubes are bracing over cross curious Claim 28: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 15, 16, 18, 20, 21, 23, 24, 25, additionally characterized - a rubber seal at the lowest end of a Absenkrohres or Absenkrohr segment for Shielding the water pressure Claim 29: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 13, 15, 16, 17, 18, 20, 21, 23, 24, 25, additionally characterized: - retractable and extendable pipe segments - steel cables, attached to a flange on the lowest pipe segment and fixed in the upper chamber to electrically driven rollers - in the steel cables insulated, electrical lines for controlling the flaps in the lowermost tube segment - the smallest pipe segment is at the upper Kam - the bellows have the diameter of the smallest pipe segment - the lowest pipe segment has an inwardly directed flange Claim 30: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 13, 15, 16, 17, 18, 20, 21, 23, 24, 25, additionally characterized: - one- and extendable pipe segments - Steel cables, on a flange attached to the lowest tube segment and in the upper chamber to electrical attached motorized rollers - insulated in steel cables, electrical lines for controlling the flaps in the lowest pipe segment - the largest pipe segment is attached to the upper chamber - the bellows is in single Balg segments, divided to match the respective pipe segment - at the bottom At the end of each bellows segment there is a stability grid inside - the lowest Pipe segment has an outward-facing flange Claim 31: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 12, 13, 20, 21, 23, additionally characterized - Building with inner and outer chamber - inner Chamber as isolated water chamber - Struts in the water chamber in even height intervals to Stabilization of the walls - in the outer chamber around the water chamber several Kraftnutzungskammern - in the top floor of the outer chamber over the Kraftnutzungskammer the chambers with risers and water turbines, next to it in separate chambers flywheels and generators - in the Water chamber Scots (open vertically or horizontally) Claim 32: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 8, 9, 12, 13, 19, 20, 21, 23, 31, additionally characterized - Tank with inner and outer chamber - inner Chamber isolated as a water tank - around the inner tank in the outer chamber the force utilization units - over the power units in upper chambers the risers with water turbines, next to it in separate Chambers flywheels and small generators - in the open spaces under the generators if necessary plants for hydrogen production or electrical installations for hot water production - in the Water chamber Scots (open vertically or horizontally) Claim 33: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 8, 9, 14, 15, 16, 17, 18, 19, 20, 21, 23, 24, 25, 28, 29, 30, 32, in addition characterized: - Reinforcement grid in the larger folds of the bellows to prevent unwanted deformations Claim 34: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 14, 15, 16, 17, 18, 19, 20, 21, 23, 24, 25, 26, 27, 29, 30, 31, 32, 33, in addition characterized: - movable, air-filled Lamellae on the sides of a buoyancy piston - slippery outsides of these slats - conical Flattening of the lower ends of the pipe segments - a flange at the top of each Absenkrohrsegments for spacing Claim 35: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 12, 19, 20, 21, 23, 26, 28, 29, 30, in addition thereto characterized: - one or several lowering tubes on a support structure - a chamber with water turbine, electrics, dynamo and compressed air system on this supporting structure - one long riser, vertical or diagonal - If necessary, a seawater desalination plant in the upper chamber Claim 36: Device and method for using hydrostatic energy according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 12, 19, 20, 21, 23, 29, 30, 33, 34, 35, additionally characterized: - the installations are mounted on a ship in such a way that the upper chambers protrude over the sides of the ship - under the upper chambers are retractable and retractable lowering pipes attached, retracted the water surface do not touch - the Absenkrohre have a oval or diamond shape, the narrow side in the direction of travel of the ship - in the upper chambers are the risers with water turbines - flywheels and generators are located to the side of the chambers on the ship deck - on the deck of the ship is a seawater desalination plant - on the rear deck are one or Several electro-powered amphibious vehicles and an electric charging station - in the belly of the ship are tanks for drinking water from the sea, possibly plastic canisters and bottles - at the stern of the ship a ramp for the extension and retraction of amphibious vehicles Claim 37: Device and method for using hydrostatic energy according to claim 1, 2, 3, 5, 6, 7, 8, 9, 12, 21, 23, 24, 25, 28, 29, 30, 34, 35, in addition thereto characterized: - bracing for stabilizing the lowering tubes on a supporting structure in a clear water, however not firmly attached to them, but only enclosed