DE102018007956A1 - Flow amplification system for flow power plants - Google Patents

Abstract

The flow amplification system for flow power plants provides a two-stage flow restriction for flow acceleration for the use of flow power plants. In the first stage, the flow is narrowed horizontally using a horizontally designed flow funnel (10, 110). For this purpose, two lying hollow bodies (11, 111) are used, which are shaped in the base area as a trapezoidal quadrilateral. These are connected to each other, lying on the shorter side of the head, and lowered to the bottom of a stream. A horizontally narrowing flow funnel (10, 110) with an inlet funnel (12, 112) to the front, a flow channel (14, 114) in the middle and an outlet funnel (13, 113) as a horizontal distance between the two head sides Diffuser funnel, in the second stage, a vertical cross-section trapezoidal ceiling threshold (21, 121) and a vertical cross-section trapezoidal threshold (23, 123) are installed in the flow channel (14, 114) of the horizontal flow funnel (10, 110). The flow, which has already been narrowed down with the horizontal flow funnel (10, 110), is again vertically restricted and the flow is accelerated further According to the state of the art in flow power plants, the turbines are simply hung into the flow and only the existing flow velocity of the flow water is used the prior art, either smaller and therefore cheaper turbines are used for the same power output, or an h with the same turbine size higher power output can be achieved. This results in cost advantages for turbine investment, maintenance and repair costs.

Description

The present invention relates to a flow amplification system for flow power plants, with which the flow in flow waters is selectively amplified with flow funnels and the flow-accelerated water hereby passed on to a flow channel for a flow power plant for electricity generation and then discharged again via a diffuser funnel.

Classic hydroelectric power plants with backwater often use the potential energy due to the fall height with transverse structures (dam walls). This requires the damming of water with the associated environmental problems of the lack of continuity in the rivers for flora and fauna, especially for fish.

Flow power plants that work without dams are an alternative. The state of the art is that until now, turbines were simply hung in the flow to generate electricity in streams, often with floating devices that are attached to the bottom of the body of water or on the river bank. The common feature of the current power plants is that the turbines are simply hung or installed in the flow of the water and only the current strength of the flow water can be used. According to the prior art, a flow velocity of at least 2 m / s is required for these floating flow power plants for the economical generation of electricity.

The problem here is that there are only a few rivers where this required flow velocity of at least 2 m / s is available. Thus, the enormous potential of the kinetic energy in the flow waters, which for the most part is at flow speeds of significantly below 2 m / s, cannot be used economically according to the prior art.

The object of the present invention is to find a device for amplifying the existing flow rate in the flow waters, with which compared to the previously used flow power plants, which only use the existing flow rate for power generation, due to a flow amplification achieved either with smaller and thus less expensive turbines same power can be achieved, or higher power is possible with the same turbine size. In addition to the flow amplification, the device should be the structural basis for the installation of the devices and turbines for the flow power plant to be installed.

The solution to the problem outlined above is provided by the flow amplification system for flow power plants described below for accelerating the flow of water.

A horizontal flow funnel is created for the flow enhancement system. Two horizontal trapezoidal hollow bodies are used for this purpose, the outer walls of which are made of waterproof material. The hollow bodies trapezoidal in horizontal cross-section are then folded over and lying with the shorter head side against each other, lowered to the bottom of a stream and connected with rod-shaped connecting elements, whereby a horizontal flow funnel is formed by a horizontal distance between the two head sides of the lying hollow bodies is open at the top, with a horizontal inlet funnel to the front, a horizontal diffuser funnel to the rear and a horizontal flow channel in the middle.

The distance between the two trapezoidal hollow bodies is determined by the planned flow restriction, the current flow strength, the length of the trapezoidal hollow bodies and the existing water depth. Simulation calculations are helpful for this.

The incoming flow is restricted and accelerated in the horizontal inlet funnel. The flow accelerated in this way is passed on to the horizontal flow channel, which is formed in the middle of the horizontal flow funnel and is intended for turbine installation. The flow is slowed down again via the rear horizontal diffuser funnel to the outlet side and the flow water is returned from the flow funnel into the flow water.

The horizontal flow funnel is open to the top. In contrast to funnels with a closed wall, turbulent water masses that arise when the flow is restricted can flow out to the top. This improves the flow velocity gain in the horizontal flow funnel.

A further flow restriction and an additional flow acceleration resulting therefrom takes place with a hollow body trapezoidal in vertical cross section as a ceiling threshold, the outer walls of which are made of a waterproof material.

The ceiling trapezoidal in vertical cross section becomes the top of the horizontal flow funnel, with the narrow side of the head downwards, transversely into the middle of the horizontal flow channel installed, with an additional vertical flow restriction with flow amplification results in the flow channel.

The interior of the ceiling trapezoidal vertical cross section is intended for the assembly of devices and the underside for the installation of turbines or other converters for a flow power plant, the vertical cross section of the trapezoidal ceiling sleeper with the converters and devices of the flow power plant being lifted up for maintenance and repair work and can be returned.

A further flow restriction and an additional flow acceleration resulting therefrom takes place with a component made of waterproof material with a trapezoidal vertical cross section, which for additional vertical flow restriction as a threshold, with the narrow head side upwards and below the trapezoidal cross section in the vertical cross section, running transversely in the horizontal flow channel is placed on the bottom of the water.

By spacing the top side of the threshold, which is trapezoidal in vertical cross section, from the top of the ceiling threshold, which is trapezoidal in vertical cross section, there is a vertical flow channel and an additional vertical flow restriction with flow amplification between the two head sides.

The distance between the ceiling threshold and the floor threshold for the vertical flow restriction to be carried out can be designed to be project-specific.

Through two beam-shaped concrete plinths, which are attached in the direction of flow on the two outer sides to the underside of the threshold, a passage channel for fish and the bed load is formed between the underside of the threshold and the water bed. The height of the passage channel is determined by the height of the plinth supports.

The further object of the present invention is to find a device for flow power plants for increasing the existing flow velocity in the flowing water, which can either be installed floating on the surface of the flowing water or floating in a determinable water depth and also lowered on the water bed. The device is also intended to show solutions for the use of undercutting converters, such as water wheels or treadmill turbines. The solution to this is provided by the floating flow amplification system for flow power plants described below.

The basic components are two horizontal hollow bodies, the outer walls of which are made of water-resistant material, the base of which is shaped as a trapezoidal quadrilateral, closed at the top and bottom and provided with flooding slots on at least one outside. As a result, the hollow bodies are flooded when lowered into the flow water and emptied when the flow water is taken out.

The hollow bodies are fastened against each other on a base plate with the shorter head side, whereby a horizontal inlet funnel and a horizontal diffuser funnel and a horizontal flow channel in the middle are formed by a horizontal distance between the two head sides of the lying hollow bodies. To shift the center of gravity downwards, the two hollow bodies are loaded with stone material or other load material on the floor and equipped with inflatable air bodies with a valve for regulating the swimming height. The distance between the two trapezoidal hollow bodies for the flow restriction to be carried out and thus the width of the horizontal flow channel resulting therefrom can be made variable.

A cover plate is attached to the top of the floatable flow funnel, which covers the entire top side, the cover plate being provided with a cutout in the horizontal cross section of the converter to be installed in the case of the installation of an undershot converter, such as a water wheel or a treadmill turbine, whereby the upper one Part of the converter protrudes outdoors.

This forms a floating flow funnel with horizontal flow restriction, which is provided with a bottom plate at the bottom and a cover plate at the top. Turbines or other converters and devices for a flow power plant are installed in the flow channel of the floatable flow funnel.

For further flow reinforcement, a hollow body component made of waterproof material with a narrow head side down is installed in the flow channel of the floatable flow funnel as a threshold.

In addition, a component made of waterproof material with a trapezoidal vertical cross-section, with flooding slots on at least one outside, as a threshold, with the narrow one Head side up, running in the middle of the horizontal flow channel, installed under the trapezoidal ceiling sill. By a distance from the head side of the ceiling sill trapezoidal in vertical cross section to the top side of the floor sill trapezoidal in vertical cross section below, a further flow constriction is formed between the two head sides, with a vertical flow channel in the middle. The distance between the head sides of the threshold and the ceiling can be designed variably and is determined by the planned flow restriction and the current flow strength.

For the flow amplification system, for the installation of treadmill-shaped converters to the lower side of the ceiling cross section of the flow funnel, which is trapezoidal in vertical cross-section, a cuboid recess is formed with curved roundings on the narrow front and end sides, so that the upper half is shielded from the incoming flow when installing treadmill-shaped converters .

When installing treadmill-shaped converters, it is provided that the vertical cross-section trapezoidal threshold to the top and, alternatively, for one-sided operation, additionally with an attachment that is ramp-shaped, starting from the flow inlet side. With the ramp-shaped configuration, part of the input flow and turbulence forming in the inlet funnel of the vertical flow constriction is passed on to the rear blades of the water treadmill turbine and thus the performance of the treadmill converter is improved.

The floating flow funnel can also be installed floating on the surface of the water for the use of converters, such as water wheels or treadmill turbines, whereby the immersion depth can be variably designed by changing the amount of air in the air bodies of the hollow bodies trapezoidal in horizontal cross section.

For use as a floating berth and / or for planting on the cover plate, protective railings and / or protective grilles are attached to the flow funnel which is mounted and fastened floating on the surface of the water on the top cover plate.

For use in tidal waters with changing flow directions, the inlet and outlet funnels of the flow funnel, as well as the trapezoidal threshold and the trapezoidal threshold are formed symmetrically to the front and rear. This results in the same input sides with the same angle sizes when the flow changes. Several flow funnels can be connected to flow funnel module chains and several module chains to a flow funnel module field, with the electricity generated by the flow power plants installed in the flow funnels being transported to the mainland using a power transport cable.

If required, a metal protective grille against flotsam is attached to the outlet and / or inlet of the flow funnel, depending on the application.

To use the energy of flows that are already contained in pipes, a floating flow funnel is used as a pipe flow funnel, with an input element being attached to the inlet side of the pipe flow funnel, in which a tubular water inlet is transferred to a rectangular funnel, which in the end is at its height and corresponds to the width of the inlet opening of the tube flow funnel and to the outlet side of the tube flow funnel an output element in reverse arrangement, the rectangular outlet funnel of the tube flow funnel being transferred into a tubular drain. The flow used to generate energy can thus be derived in tubular form again. The pipe flow funnel can also be installed outside of water.

With the floating flow funnel, a trapezoidal cutout can be made to the size of the top of the horizontal input funnel to the top of the horizontal inlet funnel, so that turbulent water masses that arise when the flow is constricted can flow out through the open top of the horizontal inlet funnel. This increases the flow velocity in the horizontal inlet funnel.

To discharge turbulence at the horizontal inlet funnel, continuous, horizontal pipes are provided to the front of the hollow body, which has a trapezoidal cross-section in the horizontal cross section, with which turbulent flow water at the horizontal inlet funnel is bypassed, bypassing the converters, into the outlet funnel, which acts as a diffuser funnel, to the rear. This improves the performance of the flow power plant to be installed.

• 1 einen horizontalen Strömungstrichter, der nach oben offen ist, mit mittseitigem Strömungskanal, im horizontalen Schnitt,
• 2 die Ausbildung einer vertikalen Strömungseinengung mit Bodenschwelle und Deckenschwelle und mit mittseitigem Strömungskanal, im vertikalen Schnitt,
• 3 einen Strömungstrichter mit horizontaler und vertikaler Strömungseinengung und einem Durchgängigkeitskanal zur Unterseite, im vertikalen Schnitt zur Vorderseite,
• 4 a ein trapezförmiges Seitenteil des schwimmfähigen Strömungstrichters, mit Öffnungen zur Wasserbefüllung und -entleerung,
• 4 b einen schwimmfähigen Strömungstrichter, mit mittseitigem Strömungskanal und Bodenplatte, im horizontalen Querschnitt,
• 4 c einen schwimmfähigen Strömungstrichter, mit Belastungsmaterial und Luftkörper in den beiden Seitenteilen und mittseitigem Strömungskanal, mit eingebauter Deckplatte und einer Bodenplatte, im vertikalen Schnitt,
• 5 einen schwimmfähigen Strömungstrichter mit Boden- und Deckplatte, mit Belastungsmaterial und Luftkörper in beiden Seitenteilen und mittseitigem Strömungskanal, mit eingebauter Deckenschwelle und Bodenschwelle, zur Ausbildung eines vertikalen Strömungskanals, im vertikalen Schnitt zur Vorderseite,
• 6 eine Deckplatte für den schwimmfähigen Strömungstrichter, mit Ausschnitt zum Einbau eines Wasserrades oder einer Laufbandturbine und mit Schutzgittern an den Außenseiten, zur zusätzlichen Nutzung als Liegeplattform und/oder zur Bepflanzung,
• 7 die Ausbildung einer vertikalen Strömungseinengung, mit mittseitigem Strömungskanal und einer quaderförmigen Aussparung zur Unterseite der Deckenschwelle, im vertikalen Schnitt,
• 8 die Ausbildung einer vertikalen Strömungseinengung, mit mittseitigem Strömungskanal und einer Aussparung zur Unterseite der Deckenschwelle nach 7 und einer zusätzlichen rampenförmigen Ausformung zur Oberseite der Bodenschwelle, im vertikalen Schnitt,
• 9 durchgehende Turbulenzabführrohre an den zwei liegenden, im horizontalen Querschnitt trapezförmigen Hohlkörpern des Strömungstrichters, im horizontalen Schnitt,
• 10 den schwimmfähigen Strömungstrichter, mit offener Oberseite des Eingangstrichters
• 11 einen Rohrströmungstrichter mit rohrförmigen Übergangselementen zur Eingangs- und Ausgangsseite,
• 12 ein Strömungstrichtermodulfeld für den Gezeiteneinsatz der Strömungstrichter.

Further details and advantages of the present invention result from the following drawings with a description of an embodiment. The drawings are created as examples and without using a scale.
Show it:

• 1 a horizontal flow funnel, which is open at the top, with a central flow channel, in a horizontal section,
• 2nd the formation of a vertical flow restriction with threshold and ceiling threshold and with a central flow channel, in a vertical section,
• 3rd a flow funnel with horizontal and vertical flow restriction and a passage channel to the bottom, in a vertical section to the front,
• 4 a a trapezoidal side part of the buoyant flow funnel, with openings for water filling and emptying,
• 4 b a floatable flow funnel, with a central flow channel and base plate, in horizontal cross-section,
• 4 c a floating flow funnel, with loading material and air body in the two side parts and central flow channel, with built-in cover plate and a base plate, in vertical section,
• 5 a buoyant flow funnel with base and cover plate, with loading material and air body in both side parts and central flow channel, with built-in threshold and threshold, to form a vertical flow channel, in vertical section to the front,
• 6 a cover plate for the buoyant flow funnel, with cut-out for installing a water wheel or a treadmill turbine and with protective grilles on the outside, for additional use as a deck platform and / or for planting,
• 7 the formation of a vertical flow restriction, with a flow channel in the middle and a cuboid recess to the underside of the threshold, in a vertical section,
• 8th the formation of a vertical flow constriction, with a central flow channel and a recess to the underside of the threshold 7 and an additional ramp-like shape to the top of the threshold, in a vertical section,
• 9 continuous turbulence discharge pipes on the two horizontal, trapezoidal hollow bodies of the flow funnel, in horizontal section,
• 10th the buoyant flow funnel, with the top of the inlet funnel open
• 11 a tubular flow funnel with tubular transition elements to the inlet and outlet side,
• 12th a flow funnel module field for the tidal use of the flow funnels.

In 1 becomes the formation of a horizontal flow funnel 10th , which is open at the top. This consists of two horizontal, horizontal trapezoidal hollow bodies 11 , which are open to the bottom and top, and whose outer walls are made of waterproof material. The horizontal trapezoidal hollow body 11 are lying with the shorter head side against each other, lowered to the bottom of a stream and at a designated horizontal distance between the two head sides with rod-shaped connecting elements 28 associated with each other. The horizontal distance between the two sides of the head creates a horizontally narrowing flow funnel 10th , which is open at the top, formed with a horizontal flow channel 14 in the middle, as well as an entrance funnel 12th and an exit funnel 13 . In 1 is the horizontal distance for the formation of the flow channel 14 exactly 50% of the total width of the horizontal flow funnel 10th .

The incoming flow is thus in the entrance funnel 12th narrowed horizontally and thus accelerated to the horizontal flow channel 14 guided. The exit funnel 13 to the opposite rear acts as a diffuser funnel. The two hollow bodies, trapezoidal in horizontal cross section 11 , are filled with stone material and / or other load material after lowering on the body of water to ensure traction, with which the required traction is achieved in the majority of applications. In the case of very strong currents, the hollow body, which is trapezoidal in horizontal cross section, can be additionally fastened 11 at the bottom of the water with metal posts 27 respectively.

This cost-effective method has the advantage that the hollow body is trapezoidal in horizontal cross section 11 Compared to solid elements, due to the much lower weight, they are easier to transport and can be lowered more easily on site. When filling the trapezoidal hollow body 11 with stone material, this lies seamlessly on the water floor and is therefore more stable than a floor slab on the underside.

The horizontal flow funnel 10th is open to the top. In contrast to funnels with a closed wall, turbulent water masses that arise when the flow is restricted can flow out to the top. So that with the horizontal flow funnel 10th the reinforcement the flow velocity in the horizontal flow funnel 10th improved.

The one in the flow channel 14 Transducers for flow power plants to be attached are thus acted upon by a flow with increased speed. The angular size of the input and output funnel 12th , 13 can be designed variably according to the fluidic requirements. In 1 based on a simulation calculation, an angle size of 22.5 degrees was used.

2nd shows a vertical flow restriction with formation of a vertical flow channel 26 . For this purpose, a threshold that is trapezoidal in vertical cross-section becomes on the floor side 23 , with the narrow side of the head upwards, running transversely into the horizontal flow channel 14 of the horizontal flow funnel 10th placed on the bottom of the water. The upper part is a threshold 21 with flood slots 29 , with the narrow side of the head downwards, over the vertical trapezoidal threshold 23 , running in the middle of the horizontal flow channel 14 built-in. By a distance from the head side, the vertical cross-section of the threshold 21 , to the head of the threshold below, which is trapezoidal in vertical cross-section 23 , is in the horizontal flow channel 14 another vertical flow channel 26 educated. This results in an additional vertical flow restriction with flow amplification.

3rd shows the entire structure of the flow amplification system for flow power plants in vertical section to the front. With the two trapezoidal hollow bodies 11 , which are lowered and fastened to the bottom of the flow water, becomes a horizontal flow funnel 10th , with a horizontal flow channel 14 trained and thus narrowed and strengthened the flow horizontally. In 3rd this flow restriction is 50% of the entrance width of the horizontal flow funnel 10th . In the horizontal flow channel 14 is a ceiling threshold above 21 built-in. So that the flow in the horizontal flow channel 14 additionally concentrated and accelerated from above. It is also in the horizontal flow channel 14 also a threshold 23 under the threshold 21 built-in. So that is in the horizontal flow channel 14 another vertical flow channel 26 trained and the flow is additionally narrowed vertically, which results in a further flow acceleration. With two beam-shaped plinths 31 made of concrete, which flows in the direction of flow on the two outer sides to the underside of the threshold 23 will be attached between the bottom of the threshold 23 and a passage channel on the bottom of the water 30th trained for flora, fauna and water attachments. With the height of the plinths 31 becomes the height of the patency channel 30th certainly.

4 a shows the lying hollow body used as a basic component for the floating flow funnel 111 , which is shaped as a trapezoidal square in the base, and is closed at the top and bottom. On the top and on the broad side are the flooding slots 15 to be seen, which are attached to at least one outside.

4 b shows two of the hollow bodies 111 out 4a , lying with the shorter head side against each other, on a base plate 118 be applied, with a horizontal distance between the two sides of the head of the lying hollow body 111 a horizontal entrance funnel to the front 112 and a horizontal exit funnel to the rear 113 , as well as a horizontal flow channel 114 in the middle. With that the incoming flow in the entrance funnel 118 constricted and thus the flow accelerated the flow channel 114 fed.

4 c shows, in vertical section to the front, a buoyant flow funnel 110 with a horizontal flow restriction. Here, the two hollow bodies 111 , which are shaped trapezoidal in the base and closed to the top and bottom, on a bottom plate 118 mounted, this hollow body 111 with the smaller head side lying against each other. By a distance between the two sides of the head of the hollow body 111 becomes a horizontal flow channel 114 educated. The two hollow bodies 111 are for shifting the center of gravity downwards, on the ground with stone material 116 or other load material 116 loaded and with an inflatable air body 117 equipped to regulate the swimming height. To the top of the trapezoidal hollow body 111 is a cover plate 119 upset.

5 shows the flow enhancement system of 4 c , in addition to this a threshold trapezoidal in vertical cross section 123 with the narrow side of the head upwards, running across the horizontal flow channel 114 of the horizontal flow funnel 110 is installed. The upper part is a ceiling trapezoidal vertical cross section 121 , with the narrow side of the head downwards, over the vertical trapezoidal threshold 123 , running in the middle of the horizontal flow channel 114 built-in. By a distance from the head side, the vertical cross-section of the threshold 121 , to the head of the threshold below, which is trapezoidal in vertical cross-section 123 , is in the horizontal Flow channel 114 another vertical flow channel 126 educated. This results in an additional, vertical flow restriction with flow amplification. 5 shows a two-stage flow amplification system, whereby a horizontal flow funnel is first created, and in its horizontal flow channel 114 vertical flow amplification is additionally formed. The flow is thus narrowed and accelerated in two stages.

As in 6 is shown for mounting an undershot converter, such as a water wheel or a water belt turbine, on the top of the floatable flow funnel 110 applied cover 119 a section 140 through which the transducers intended for installation protrude with the top into the open. As in 6 are shown for use as a floating berth and / or for planting on the cover 119 with the floating funnel mounted and fastened on the surface of the water 110 , on the top cover 119 guardrails to the outside 160 and / or protective elements 160 appropriate. The buoyant flow funnel 110 can thus be used as an energy island for power generation and leisure activities.

7 shows a vertical cross section trapezoidal threshold 21 , 121 , with a rectangular recess on the lower side 22 , with arched curves on the narrow front and back sides, which is intended for the installation of a treadmill-shaped converter. With this recess 22 , 122 the upper part of a treadmill-shaped converter is to be shielded from the flow. An additional, vertical flow channel is formed with the threshold, 23, 123, which is trapezoidal in vertical cross section and located below 26 , 126 trained, resulting in an additional flow restriction with flow acceleration.

8th differs from 7 in that on the top of the vertical cross section trapezoidal threshold 23 , 123 a ramp 33 rising to the entrance side, is formed. This means that only part of the input flow hits the front water blades of the treadmill turbine to be installed. The remaining part of the inlet flow meets the water blades behind the treadmill turbine and at the same time leads in the inlet funnel 26 , 126 formed turbulence backwards. This increases the performance of the treadmill turbine.

9 shows how to dissipate turbulence at the horizontal inlet funnel 12th , 112 , to the front of the two trapezoidal hollow bodies 11 , 111 , continuous, horizontal pipes as turbulence discharge pipes 70 are introduced with which turbulent flow water at the horizontal inlet funnel 12th , 112 , bypassing the converters, into the exit funnel 13 , 113 is directed to the back. This improves the performance of the flow power plant to be installed.

10th shows the buoyant flow funnel 110 , at the top of the horizontal entrance funnel 112 a trapezoidal neckline 131 the size of the top of the horizontal entrance funnel 112 is made, which means through the open top of the horizontal entrance funnel 112 turbulent water masses that arise when the flow is restricted can flow upwards. This increases the flow velocity in the horizontal inlet funnel 112 improved.

11 shows a pipe flow funnel 280 , which is used when the flow for energy generation is already contained in pipes. Here is on the input side 212 of the pipe flow funnel 280 an input element 227 attached, in which a tubular water access is transferred into a rectangular funnel, which in the end in height and width of the inlet opening of the pipe flow funnel 280 corresponds. To the exit page 213 of the pipe flow funnel 280 is an output element 228 attached in reverse order, with the rectangular exit funnel 213 of the pipe flow funnel 280 is transferred to a tubular drain. The flow used to generate energy can thus be derived in tubular form again. The installation of the pipe flow funnel 280 with the tubular input element 227 and the output element 228 is possible in the water and also on land.

12th shows the use of flow funnels 10th , 110 in tidal waters with changing flow directions as a module field, with at least two flow funnels for use in tidal waters 10th , 110 with a flow funnel connection cable 310 which also leads to the power line in the funnels 10th , 110 to be installed flow power plants is prepared to a flow funnel module chain 315 get connected. At least two flow funnel module chains 315 with a module chain connection cable 320 which also leads to the power line for those in the flow funnels 10th , 110 to be installed flow power plants is prepared to a flow funnel module field 325 connected and wherein at least two module chain connecting cables 320 into a power cable 330 transferred with which the current generated is that in the flow funnels 10th , 110 installed power plants is transported to the mainland.

• Systembasis ist der horizontale Strömungstrichter, der aus zwei trapezförmigen Hohlkörpern besteht. In dem ausgebildeten horizontalen Strömungskanal des Strömungstrichters werden Strömungskraftwerke eingebaut werden.

The flow amplification system for flow power plants has a modular design and can be created and installed in the following stage variants, depending on the conditions of the existing flow waters:

• The system is based on the horizontal flow funnel, which consists of two trapezoidal hollow bodies. Flow power plants will be installed in the horizontal flow channel of the flow funnel.

For further flow reinforcement, a ceiling sill trapezoidal in vertical cross section is installed as a hollow body at the top of the horizontal flow channel. The turbines are installed on the underside of the threshold and the devices for flow power plants are installed inside.

The final stage of the flow amplification takes place with the additional installation of a threshold which is trapezoidal in vertical cross section. With this, a vertical flow reinforcement is simultaneously formed in the horizontal flow channel.

For use in tidal waters, flow module chains can be created with connecting cables and several module chains can be connected to form a flow module field.

• ein Durchgängigkeitskanal zur Bodenseite für Fische und dem natürlichen Gewässergeschiebe, ein Schutzgitter gegen Treibgut zur Rückseite und/oder Vorderseite und
• für Laufbandturbinen eine Aussparung zur Unterseite der Deckenschwelle und eine zusätzliche Rampe zur Oberseite der Bodenschwelle.

The following can be installed as additional components:

• a passage channel to the bottom for fish and the natural bed load, a protective grille against flotsam to the rear and / or front and
• for treadmill turbines, a recess to the underside of the threshold and an additional ramp to the top of the threshold.

Innovative advantages

• Während bisher für Strömungskraftwerke, bei denen die Turbinen nach dem Stand der Technik nur einfach in die Strömung eingehängt werden, nur die vorhandene Strömungsgeschwindigkeit des Strömungsgewassers genutzt werden kann, kann mit dem Strömungsverstärkungssystem für Strömungskraftwerke die vorhandenen Strömungsgeschwindigkeit um den Faktor 1,5 bis 2,0 gesteigert werden. Die Produktivität der Stromerzeugung kann damit, gegenüber den bisher eingesetzten Strömungskraftwerken, bei denen die Turbinen nur einfach in die Strömung eingehängt werden, um ein Mehrfaches gesteigert werden, wobei die 3. Potenz bei der Stromleistung zum Tragen kommt. Infolge der erzielten Strömungsverstärkung können mit dem Strömungsverstärkungssystem für Strömungskraftwerke, gegenüber dem Stand der Technik, entweder kleineren und damit kostengünstigeren Turbinen für die gleiche Stromleistung eingesetzt werden, oder es kann bei gleicher Turbinengröße eine höhere Stromleistung erzielt werden. Hieraus ergeben sich Kostenvorteile bei der Turbineninvestition, Wartung und den Reparaturkosten.

The flow enhancement system for flow power plants has the following innovation advantages:

• So far, only the existing flow velocity of the flow water can be used for flow power plants in which the turbines according to the prior art are simply hung into the flow, with the flow amplification system for flow power plants the existing flow speed can be increased by a factor of 1.5 to 2. 0 can be increased. The productivity of power generation can thus be increased many times over compared to the current power plants in which the turbines are simply hung in the flow, the third power being used in the power output. As a result of the flow amplification achieved, with the flow amplification system for flow power plants, compared to the prior art, either smaller and therefore less expensive turbines can be used for the same current output, or a higher current output can be achieved with the same turbine size. This results in cost advantages in turbine investment, maintenance and repair costs.

In a model test in a flow channel, the horizontal flow funnel with a flow restriction on a third of the inlet surface of the flow funnel resulted in a flow gain with a factor of 1.6 and with a further flow restriction, with floor and ceiling threshold, a flow gain with a quarter of the input surface the factor 1.9. In the first case, using the flow funnel with the same turbine size, 4 times the power output can be generated and in the second case 6.85 times the power output.

Whereas a flow rate of at least 2 m / s was previously required for the economical generation of electricity for flow power plants according to the state of the art, with the flow amplification system for flow power plants flow waters with an existing flow rate of approx. 1.5 m / s can already be used economically for electricity generation. With the flow amplification system, a large amount of the existing kinetic energy potential can additionally be converted into electrical current in an environmentally friendly manner which, according to the state of the art, has so far not been able to be used economically.

Another, if not financially measurable, innovation point is that the flow enhancement system, in contrast to the current power plants floating on the surface of the body of water, can also be lowered on the bottom of the body of water. This means that there is no visible disturbance in the river landscape.

The horizontal flow funnel is open to the top. In contrast to funnels with a closed wall, turbulent water masses that arise when the flow is restricted can flow out to the top. This improves the flow velocity gain in the horizontal flow funnel.

Another advantage for the flow amplification system for flow power plants is the horizontal design of the flow funnel, which can be created at heights from 1 m. This means that it can be used in streams with very low water depths.

With the help of the horizontal trapezoidal hollow bodies, which are provided with loading material and inflatable air bodies and flooding openings in the interior, the floatable flow funnel can be installed with a ready-to-use flow power plant floating in the flow water on the surface, floating in any water depth or lowered on the water bed. The depth of use can also be changed at any time using the air volume of the air bodies. If the flow conditions change, the installation depth can be changed.

The cover plate of the flow funnel floating on the surface of the water can be provided with protective devices on the outside and can thus also be used as a floating energy island with a berth or for planting.

Claims (10)

Flow amplification system for flow power plants for accelerating the flow of water, consisting of a horizontal flow funnel (10) which is open at the top, with a horizontal inlet funnel (12) for flow reinforcement, a horizontal flow channel (14) to the center, for turbine installation, a horizontal outlet funnel ( 13) as a diffuser funnel, and a ceiling sill (21) trapezoidal in vertical cross-section and a floor sill (23) trapezoidal in vertical cross-section, with plinths (31) to the underside, characterized by : two horizontal, horizontal cross-section-shaped hollow bodies (11) that are open to the top and bottom, and the outer walls are made of water-resistant material, these, in the horizontal cross-section trapezoidal hollow body (11), lying with the shorter head side against each other, lowered to the bottom of a stream and with rod-shaped connecting elements elements (28) are connected to one another and fastened to the bottom of the water, a horizontal flow funnel (10) which is open at the top being formed by a horizontal distance between the two head sides of the lying hollow body (11) which is trapezoidal in horizontal cross section , with a horizontal inlet funnel (12) to the front, a horizontal outlet funnel (13) as a diffuser funnel, to the rear and a horizontal flow channel (14) in the middle, and the two lying, trapezoidal hollow bodies (11) in the base, which are open to the bottom and top, after lowering on the water floor with fastening piles (27) attached to the water bottom and filled with stone material and / or other load material for adherence, whereby turbulent water masses through the open top of the horizontal flow funnel (10) when the flow in the horizontal inlet funnel ( 12), flow upwards and the flow velocity in the horizontal inlet funnel (12) is more effective, a vertical trapezoidal hollow body as a ceiling threshold (21), the outer walls made of waterproof material and with slot-like openings as flooding slots (29 ) are provided on at least one outside, for watering and draining the ceiling sill (21) during installation and removal, and the ceiling sill (21), which is trapezoidal in vertical cross section, towards the top of the horizontal flow funnel (10) with the narrow head side below, transversely into the middle of the horizontal flow channel (14), whereby in the horizontal flow channel (14) there is an additional, vertical flow restriction with flow amplification, and wherein the interior of the trapezoidal vertical cross section and the underside thereof Assembly of Devices, as well as turbines or other converters for flow power plants are intended, and wherein the ceiling trapezoidal vertical cross section (21) can be lifted up and returned with the converters and devices of the flow power plant for maintenance and repair work, a component trapezoidal in vertical cross section made of water-resistant material, which is installed as a threshold (23), with the narrow head side upwards and below the trapezoidal ceiling sill (21), transverse to the horizontal flow channel (14), for additional vertical flow restriction on the water bottom, whereby by a distance from the head side of the threshold (23) trapezoidal in vertical cross section to the top of the ceiling threshold (21) located above it, which is trapezoidal in vertical cross section, between the two head sides a vertical flow channel (26) is formed, where with an additional, vertical flow restriction with flow amplification, and whereby through two beam-shaped base supports (31) made of waterproof concrete, which are attached in the direction of flow to the underside of the threshold (23), which is trapezoidal in vertical cross-section, between the underside of the threshold (23) which is trapezoidal in vertical cross-section and the bottom of the body of water, is trained for fish and the bed load. Flow amplification system for flow power plants with floatable flow funnels (110), characterized by : two closed hollow bodies (111) with a trapezoidal horizontal cross-section, the outer walls of which are made of waterproof material and which are each provided with flooding slots (115) on at least one outer side, and the two in the horizontal cross-section trapezoidal hollow body (111) in the interior, for loading and shifting the center of gravity downwards, load with stone material (116) or other loading material (116) on the bottom and be equipped with inflatable air bodies (117) with valve to regulate the planned installation height, a bottom-side base plate (118), made of waterproof material, on which two hollow bodies (111) trapezoidal in horizontal cross-section, with the shorter head side lying against each other and with a horizontal distance between the two head sides, are attached, whereby by the horizontal para tand the two head sides of the lying, horizontal cross-section trapezoidal hollow body (111), a horizontal flow channel (114) is formed in the middle, with a horizontal inlet funnel (112) to the front and with a horizontal outlet funnel (113) as a diffuser funnel to the rear, one top cover plate (119) made of waterproof material, with which the horizontal flow funnel (110) is covered to the top and thus a floatable flow funnel (110) is formed, and the installation depth of the floatable flow funnel (110) when installing the flow amplification system with floatable flow funnel (110) ) can be variably designed with the valve via the variable amount of air in the air bodies (117), with which the floatable flow funnel (110) can be installed floating on the water surface, floating in the current or even lowered on the water bottom, whereby at the lowering on the bottom of the body of water is then attached to the bottom of the body of water and / or on the banks of the body of water, and the depth of use can be changed at any time by changing the amount of air in the built-in air bodies (117) with valve. Flow amplification system for flow power plants according to Claim 2 , characterized in that a recess (140) is made on the top cover plate (119) of the floatable flow funnel (110) in the horizontal cross section of a converter to be installed, such as a waterwheel or a treadmill turbine, with which the upper part of these converters is installed through the recess (140) of the top cover plate (119) protrudes into the open, and wherein at the edge of the top cover plate (119) protective railings (160) are attached to the outer sides, whereby the top cover plate (119) of the floating flow funnel (110) also as a floating one Berth and / or can be used for planting. Flow amplification system for flow power plants, according to Claim 2 and 3rd , characterized by : a vertical trapezoidal hollow body as a threshold (121), the outer walls being made of waterproof material, and the vertical trapezoidal threshold (121) to the top of the floating flow funnel (110), with the narrow head side down , in the middle of the horizontal flow channel (114), under the top cover plate (119), whereby in the horizontal flow channel (114) there is an additional vertical flow restriction with a flow enhancement, and wherein the interior of the vertical cross-section-shaped ceiling sill (121), as well as their underside for mounting devices, as well as turbines or other converters for a flow power plant, and the vertical cross-section trapezoidal ceiling threshold (121) with the converters and devices of the flow power plant for maintenance and repair work to the top n can be lifted out and returned again, a vertical trapezoidal hollow body as a threshold (123), the outer walls of which are made of waterproof material, the vertical cross-section trapezoidal threshold (123), for additional vertical flow restriction, with the narrow head side upwards and under the ceiling trapezoidal vertical cross section (121), in the horizontal flow channel (114) on the base plate (118) and fastened, with a distance from the head side of the vertical cross section trapezoidal floor threshold (123) to the head side of the one above it , in the vertical cross-section trapezoidal threshold (121), a vertical flow channel (126) is formed between the two head sides, which results in an additional, vertical flow restriction with flow amplification. Flow amplification system for flow power plants according to Claim 1 and 4th , characterized in that a parallelepiped-shaped recess (22) is formed on the lower side of the ceiling threshold (21, 121) of the flow funnel (10, 110) with vertical cross-section, with arc-shaped curves on the narrow front and end sides, which means during installation of treadmill-shaped converters whose upper half is shielded from the incoming flow. Flow amplification system for flow power plants according to Claim 5 , characterized in that a ramp (33), rising from the flow inlet side, is additionally formed on the upper side of the threshold (23, 123) which is trapezoidal in vertical cross section, whereby part of the inlet flow is brought to the rear treadmill blades when treadmill-type converters are installed , resulting in less turbulence in the horizontal inlet funnel (12, 112) and in the vertical flow channel (26, 126) and with which a higher performance for treadmill-shaped converters is achieved. Flow amplification system for flow power plants, according to at least one of the Claims 2 , 4th , 5 and 6 , characterized in that a trapezoidal cutout (131) in the size of the top of the horizontal inlet funnel (112) is made on the top cover plate (119) of the floatable flow funnel (110), toward the top of the horizontal inlet funnel (112), with which the open top of the horizontal inlet funnel (112) turbulent water masses, which arise during the flow constriction, can flow upwards and thus the enhancement of the flow velocity in the horizontal inlet funnel (112) is improved. Flow amplification system for flow power plants according to at least one of the Claims 1 , 2nd , 4th and 5 , characterized in that for use in tidal waters with changing flow directions, the inlet and outlet funnels (12, 112, 13, 113) of the horizontal flow funnel (10, 110), as well as the trapezoidal ceiling threshold (21, 121) and the in vertical cross section trapezoidal threshold (23, 123) are symmetrically shaped to the front and back, and wherein for use in tidal waters at least two flow funnels (10, 110) with a flow funnel connection cable (310), which also for power conduction for those in the flow funnels (10, 110) to be installed flow power plants are prepared to be connected to a flow funnel module chain (315), and wherein at least two flow funnel module chains (315) with a module chain connection cable (320), which is also used to conduct power for those in the flow funnels (10, 110) installing flow power plants is prepared to a flow str ntermodulfeld (325), and wherein at least two module chain connecting cables (320) are transferred into a power transmission cable (330), with which the generated electricity of the flow power plants installed in the flow funnels (10, 110) is transported to the mainland. Flow amplification system for flow power plants according to at least one of the Claims 1 to 8th , characterized in that for the discharge of turbulence at the horizontal inlet funnel (12, 112), to the front of the two hollow bodies (11, 111) which are trapezoidal in horizontal cross-section in the base area, continuous, horizontally running pipes are introduced as turbulence discharge pipes (70), with which turbulent flow water at the horizontal inlet funnel (12, 112), bypassing the horizontal flow channel (14, 114), is led into the horizontal outlet funnel (13, 113) to the rear, thus resulting in less turbulence in the inlet funnel (12, 112) a performance improvement for the flow power plant to be installed is achieved. Flow amplification system for flow power plants as a tubular flow funnel (280), characterized by : two closed hollow bodies (211) with a trapezoidal horizontal cross section, the outer walls of which are made of waterproof material, a bottom plate made of waterproof material, which is shown in the drawing in 11 It cannot be seen that the two closed hollow bodies (211), trapezoidal in horizontal cross section, with the shorter head side lying opposite each other and with a horizontal distance between the two head sides, are fastened, with the horizontal distance between the two head sides of the lying horizontal cross section trapezoidal hollow body (211), a horizontal flow channel (214) is formed in the middle, with a horizontal inlet funnel (212) to the front and with a horizontal outlet funnel (213) to the rear, a top cover plate made of waterproof material, which is shown in the drawing in 11 it is not apparent what covers the tube flow funnel (280) to the top, a tube transition element (227) to the input side, which is attached to the input funnel (212) to the input side of the tube flow funnel (280), in which a tubular water access is transferred to a rectangular funnel , which at the end corresponds in height and width to the horizontal inlet funnel (212) of the pipe flow funnel (280) and a pipe transition element (228) to the outlet side at the outlet funnel (213) of the Pipe flow funnel (280), which is attached in a reverse arrangement to the pipe transition element (227) to the input side, the horizontal outlet funnel (213) of the pipe flow funnel (280) being converted into a tubular drain and the installation of turbines and devices for a flow power plant, the horizontal Flow channel (214) is provided, and at least one lockable flap (290) is attached to the top of the pipe flow funnel (280) for the installation and service of the turbines and devices to be installed, and the pipe flow funnel (280) is installed in flow waters and on land can be.

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