EP4123158A1 - Computing device and kinetic flow power plant - Google Patents

Abstract

The present invention provides a computing device for a kinetic flow power plant, comprising: a plurality of grid elements, which extend along a direction of flow from a first body to a second body, the plurality of grid elements each having a first end on the first body and a second end on attached to the second body and bent to enclose a cavity together with the first and second bodies.

Description

The present invention relates to a computing device for a kinetic flow power plant and a kinetic flow power plant with such a computing device.

In order to meet the constantly increasing demand for energy, methods for generating energy are being developed worldwide. At the same time, there is a growing need to make energy production as environmentally friendly as possible so that nature suffers less damage. With these requirements, hydropower plays an important role as a renewable energy source.

So far, electricity has been generated almost exclusively from artificially dammed water, mostly in river valleys, in fast or slow-running turbines, depending on the head. In this way, a strong intervention in nature takes place, since, among other things, the dam walls form an almost insurmountable obstacle for fish or aquatic animals are channeled through the generators. A further expansion with such power plants is therefore no longer desirable for various reasons, or only possible with difficulty and expensive and against much resistance.

An alternative way of using hydropower is to generate electricity in a river without building a weir, such as a dam. This is attempted, for example, with so-called kinetic hydroelectric power plants, which form a floating flow power plant that converts the kinetic energy of a free-flowing, undammed river into electrical energy, with the power plant unit floating slightly below the water surface.

For example, describes the EP 1 747 373 A1 a vortex turbine system for generating electrical energy in free-flowing waters with slow-running, axially loaded turbine impellers with a generator in an annular floating body.

However, living creatures and other flotsam swim past the stream buoy in free-flowing waters, especially near the surface, which can lead to collisions.

It is the object of the present invention to provide a computing device which ensures improved protection of a flow generator in a flow power plant.

According to the invention, this object is achieved by the subject matter of the independent claims.

According to a first aspect of the invention, a computing device for a kinetic flow power plant is provided. The computing device includes a plurality of grid elements, which extend along a flow direction from a first body to a second body. The several lattice elements are each fastened with a first end to the first body and with a second end to the second body and are bent in such a way that they surround a cavity together with the first and the second body.

According to a second aspect of the invention, a kinetic flow power plant is provided. The flow power plant comprises a flow generator and a suction shroud device, which is arranged downstream along a direction of flow of the flow generator is arranged and whose flow inlet opening corresponds to the external dimensions of the flow generator. In addition, the flow power plant includes a computing device according to the invention, which is arranged upstream of a flow inlet of the flow generator.

One of the ideas on which the present invention is based is to protect the flow inlet of a flow generator from foreign bodies by means of a raking device in such a way that, in addition to damaging solid bodies, aquatic creatures such as fish, for example, which could be drawn through the flow inlet of the flow generator, are reduced. In this case, the computing device is designed to allow a sufficient flow of fluid to pass in the direction of flow and to make it available to the flow generator so that it can be operated at an optimum operating point.

The grid elements are not limited to any particular material, shape, or cross-section. The grid elements can have any metal, light metal, plastic, wood or the like or composite materials. Furthermore, the lattice elements can have a polygonal, round, oval, tubular or similar cross-section. Individual ones of the plurality of lattice elements can differ in their configuration from the other lattice elements and/or vary in material and/or shape or cross-section along their length.

The direction of flow within the meaning of the present invention is defined as the predetermined direction of flow of a fluid from the first body to the second body. This means that the flow direction corresponds to the longitudinal direction of the computing device. In addition, the longitudinal direction corresponds to the Computing device with the longitudinal direction of the kinetic flow power plant, that is, the term longitudinal direction in the sense of the present invention applies to both the computing device and the flow power plant.

The cavity in the sense of the present invention refers to a volume space which is surrounded by the several lattice elements and optionally additionally by the first and/or second body in such a way that a fluid can flow through this cavity/volume space in the direction of flow, with solid foreign bodies from a certain size are prevented from entering the cavity by the computing device.

Advantageous embodiments and developments result from the dependent claims referring back to the independent claims and from the description with reference to the figures.

According to one embodiment of the computing device, the distance between the multiple grid elements, that is to say next to one another transversely to the direction of flow, is a maximum of 10 mm in each case. In this way, foreign bodies above a defined size can be deflected from the computing device.

According to a further embodiment of the computing device, the plurality of grid elements have a substantially quadrangular cross section. Thus, the lattice elements can be produced easily and cheaply. In addition, the ratio between the height and width of a lattice element can be freely selected and varied.

According to a development of the computing device, the square cross-section has an aspect ratio of width to height of at least 2 on. In this way, the computing device forms an optically more impermeable barrier in a transverse direction transverse to the flow direction, while in a transverse direction rotated 90° about the flow direction relative to the transverse direction it forms a comparatively more permeable barrier. As a result, the computing device can be optically permeable, for example when viewed from the sides and from the front, in order to only slightly influence the flow. In this case, the raking device can be optically hardly or not at all permeable from below or above, ie represent an optical barrier, so that the fish are prompted to swim around the raking device. The optical barrier is continuously weakened as the viewing direction is rotated about the flow direction from the transverse direction until the viewing direction is rotated 90° relative to the transverse direction and the computing device is optically transparent.

According to a further embodiment of the computing device, the plurality of grid elements are arranged parallel to one another. Thus, dirt and flotsam can be better deflected by the lattice elements without flotsam getting caught between the lattice elements.

According to a further embodiment of the computing device, the plurality of grid elements are arranged so that they overlap laterally relative to one another in such a way that the computing device can be rotated from an angular range of approximately 5° to approximately 175°, in particular from an angular range of approximately 15° to approximately 165°, with respect to the direction of flow considered has a closed optical barrier. An impassable obstacle can thus be optically simulated for an angular range of approximately 5° to approximately 175° in relation to the direction of flow, which causes fish to swim around it.

According to a further embodiment of the computing device, at least one of the plurality of grid elements has a varying width and/or height along its longitudinal extent from the first to the second end.

According to a further embodiment of the computing device, the hollow space surrounded by the plurality of lattice elements is designed in the shape of an egg, cone, sphere or the like. Thus, the computing device can form a streamlined shape, the flow resistance of which is lower compared to angular/cornered shapes.

According to another embodiment of the computing device, the first ends are oriented at an acute angle with respect to the direction of flow. In particular, the first ends are oriented in an angular range of 1° to 45° with respect to the longitudinal direction. In this way, the raking device can form a streamlined shape and initially easily deflect flotsam. Thus, impact shocks from the flotsam upon contact with the front of the computing device are reduced.

According to a further embodiment of the computing device, the plurality of grid elements are designed as sheet metal strips, rods or the like.

According to one embodiment, the kinetic flow power plant also has a front body which is arranged upstream of the flow generator and is connected to the flow generator and/or the suction shroud device. Thus, the front body can increase the stability of the flow power plant. In addition, the front body can absorb impacts with flotsam and thereby protect the other components of the current power plant from damage.

According to a development of the kinetic flow power plant, the first body corresponds to the front body and the second body to the flow generator or the suction jacket device. In this way, the number of components and the overall weight can be reduced.

According to a further embodiment, the kinetic flow power plant also has an adjustable hydroplane for regulating the swimming depth in the body of water, which is arranged in an edge region in relation to the longitudinal direction of the flow power plant. It is thus possible to react to changing environmental conditions. In particular, in exceptional circumstances such as flooding or icing, damage or operational disruptions can be reduced.

According to a further embodiment of the kinetic flow power plant, the front body is designed as a buoyancy body to prevent the sinking of the flow power plant. The front body can be made from a material or a combination of materials with a density of less than 997 kg/m ³ . Alternatively or additionally, the front body can contain gas inclusions whose buoyancy effect is large enough to compensate for the total weight of the hydrodynamic power plant.

According to a further embodiment of the kinetic flow power plant, the operating voltage has a maximum of 60 V. In this way, the costs for electronic components can be reduced and electrical hazards caused by defects can be reduced.

The above embodiments and developments can be combined with one another as desired, insofar as this makes sense. Further possible embodiments, developments and implementations of the invention also include combinations of features of the invention described above or below with regard to the exemplary embodiments that are not explicitly mentioned. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the present invention.

Fig. 1

eine schematische Seitenansicht eines kinetischen Strömungskraftwerks mit einer Rechenvorrichtung, deren mehrere Gitterelemente in variierenden Abständen zueinander angeordnet sind, gemäß einem weiteren Ausführungsbeispiel der Erfindung;

Fig. 2A, 2B

schematische Draufsichten jeweils eines Gitterelements einer Rechenvorrichtung gemäß Ausführungsbeispielen der Erfindung, wobei das Gitterelement in Fig. 2A eine konstante Breite und das Gitterelement in Fig. 2B eine variierende Breite aufweist;

Fig. 3

eine schematische Vorderansicht einer Rechenvorrichtung im Schnitt A-A (siehe Darstellung in Fig. 4A) mit seitlich überlappend angeordneten Gitterelementen gemäß einem weiteren Ausführungsbeispiel der Erfindung; und

Fig. 4A, 4B, 4C

schematische Ansichten (Fig. 4A: Seitenansicht; Fig. 4B: Draufsicht; Fig. 4C: isometrische Ansicht) eines kinetischen Strömungskraftwerks gemäß einem Ausführungsbeispiel der Erfindung.

The present invention is explained in more detail below using exemplary embodiments with reference to the attached figures of the drawings. From the figures show:

1

a schematic side view of a kinetic flow power plant with a computing device, the plurality of grid elements are arranged at varying distances from one another, according to a further embodiment of the invention;

Figures 2A, 2B

schematic top views of a lattice element of a computing device according to exemplary embodiments of the invention, the lattice element in Figure 2A a constant width and the lattice element in Figure 2B has a varying width;

3

a schematic front view of a computing device in section AA (see illustration in Figure 4A ) with laterally overlapping grid elements according to a further embodiment of the invention; and

Figures 4A, 4B, 4C

schematic views ( Figure 4A : side view; Figure 4B : Top view; Figure 4C : isometric view) of a kinetic flow power plant according to an embodiment of the invention.

In the figures of the drawing, elements, features and components that are the same in function and have the same effect are provided with the same reference symbols unless otherwise stated.

Although specific embodiments and modifications are illustrated and described herein, those skilled in the art will appreciate that a variety of alternative and/or similar embodiments may be substituted for the specific embodiments illustrated and described without departing from the scope of the present invention. This application is generally intended to cover any modifications or changes to the specific embodiments described herein.

The accompanying figures are intended to provide a further understanding of embodiments of the invention and, together with the description, serve to explain the principles and concepts of the invention. Other exemplary embodiments and many of the advantages mentioned will become apparent in view of the drawings. The drawings are intended to be schematic drawings only, and the elements of the drawings are not necessarily drawn to scale with respect to one another. Directional terminology such as "top", "bottom", "left", "right", "above", "below", "horizontal", "vertical", "front", "back" and similar indications are used only used for explanatory purposes and do not serve to limit the generality to specific configurations as shown in the figures.

1 shows a schematic side view of a kinetic flow power plant 1 with a computing device 20, whose several grid elements 21 are arranged at varying distances 25 from one another. The lattice elements 21 can have a different distance 25 to the lattice elements 21 extending next to them, for example. Alternatively or additionally, the lattice elements 21 can have varying distances 25 along their length, as in particular in 1 is shown. Thus, the distance 25 between two grid elements 21 arranged next to one another in the direction of flow A can increase, for example, so that no solid bodies become trapped between the grid elements 21 when the solid bodies flow past the computing device.

The flow power plant 1 can optionally include a front body 5 . The front body 5 extends, for example, in an angular range of approximately 20° to approximately 70°, in particular in an angular range of approximately 35° to approximately 55° in relation to the direction of flow A. The front element 5 is at least partially arranged in particular upstream of the computing device 20 . how 1 is illustrated as an example, the first ends 22 of the grid elements 21 can be attached to the front body 5 in such a way that the first ends 22 form a wedge-like shape in relation to the flow direction A in order to reduce the flow resistance of the flow power plant 1 .

Figures 2A and 2B show schematic top views of a grid element 21 of a computing device 20. The grid element 21 is along its longitudinal extension between a first end 22 and a second end 23 provided curved. For example, the grid element 21 in Figure 2A a constant width between the first end 22 and the second end 23. In the embodiment after Figure 2B For example, the grid element 21 has a varying width along its length from the first end 22 to the second end 23 . Alternatively or additionally, the grid element 21 in Figure 2B also vary in height.

3 shows a schematic front view of a computing device 20 in section AA with grid elements 21 arranged in a laterally overlapping manner Figure 4A shown.

The grid elements 21 of arcuate configuration are provided in an annular arrangement around a cavity 24, for example. The cavity 24 contains a volume of fluid which is suitable for flowing through a flow generator downstream of the direction of flow A. That is, the cavity 24 contains a fluid filtered by the computing device 20 to reduce the number of interfering solids in the filtered fluid. Thus, the lattice elements 21 together with the first and the second body 5, 10 surround the cavity 24. In this case, the cavity 24 surrounded by the lattice elements 21 according to FIG 3 for example be egg-shaped. Alternatively, cavity 24 may be conical, spherical, or the like. The forms mentioned are to be understood by those skilled in the art as approximate forms which are essentially streamlined, differ slightly in their actual form from the forms mentioned above and can also be combined with other forms.

Furthermore, in particular the 3 five lattice elements 21 shown by way of example in relation to a transverse direction B transverse to the flow direction A may be arranged laterally overlapping. As a result of the laterally overlapping arrangement, the computing device 20 has a closed optical barrier when viewed from this transverse direction B. Thus, fish approaching the computing device 20 from approximately the transverse direction B are caused to change course.

Furthermore, a distance 25 of the grid elements 21 transversely to the direction of flow A can be a maximum of 50 mm, in particular a maximum of 10 mm. It is irrelevant which cross-section the lattice elements 21 have. Irrespective of whether the cross-sections are round or angular, the smallest vertical, horizontal or diagonal distance between adjacent lattice elements 21 is used, for example. A person skilled in the art can determine this accordingly.

In 3 the lattice elements 21 have, for example, a substantially quadrangular cross-section, in which case the edges can be rounded off. In this case, the square cross-section has, in particular, an aspect ratio of width to height of at least 2.

Figure 4A , 4B and 4C show schematic views of a kinetic flow power plant 1. The flow power plant 1 comprises a flow generator 2, a suction shroud device 10 and a computing device 20.

The flow generator 2 has, for example, a rotor 3 whose axis of rotation is approximately in the direction of flow A or the longitudinal axis of the Current power plant 1 corresponds. The rotor 3 can be partially surrounded by the suction jacket device 10 .

The suction shroud device 10 is arranged along a flow direction A downstream of the flow generator 2 . For example, the suction shroud device 10 may include a flow inlet port 11 and a flow outlet port 12 . The flow outlet opening 12 is arranged, for example, in particular along the flow direction A downstream of the flow inlet opening 11 . In addition, the flow inlet opening 11 of the suction casing device 10 corresponds to the external dimensions of the flow generator 2. Furthermore, the suction casing device 10 can contain a plurality of casing housing segments 13, which essentially extend in the flow direction A between the flow inlet opening 11 and the flow outlet opening 12. In addition, the plurality of jacket housing segments 13 can be provided in such a way that together they form a conical jacket body. The plurality of jacket housing segments 13 can be continuously moved relative to one another between a first and a second extreme position in such a way that the flow speed inside the suction jacket device 10 can be regulated in comparison to the surrounding flow.

In this way, a variably adjustable suction shroud device 10 can be provided, which adjusts itself as a function of a flow rate of the fluid flowing against the suction shroud device 10 in such a way that the flow rate inside the suction shroud device 10, in particular at the flow inlet opening 11, is lower compared to the flow rate of the inflowing fluid deviates from a predetermined setpoint. Thus, the suction jacket device 10 for example, provide the flow rate for a flow power plant 1 that can be arranged in the flow inlet opening 11 in a desired speed range, regardless of the flow rate of the inflowing fluid. In particular, this makes it possible to bring about an optimal operating point of the flow power plant 1 .

The term extreme position refers to a state of the plurality of casing segments 13 in which the mobility of the casing segments of the plurality of casing segments 13 that are movable relative to one another is restricted in at least one direction of movement. This means that, for example, two jacket housing segments that can be pivoted towards one another are pivoted until they come into contact with one another and can therefore only be pivoted away from one another in this state. The extreme position is also present when the direction of movement is blocked by third components, such as the limited stroke of a damper or spring or other movement-blocking devices. The several jacket housing segments 13 also have an extreme position when only one degree of freedom is provided and one of the two directions of movement is blocked within this degree of freedom, for example a linear movement to the left as opposed to a linear movement to the right.

Furthermore, the suction shroud device 10 preferably has six, eight or ten shroud housing segments 13, but is not limited thereto. At least one of the jacket housing segments 13 has a flow deflection device 18 on its outer side 17, as shown in particular in Figure 4A and 4B is shown. The flow deflection device 18 is designed to increase the fluid-mechanical resistance to a fluid flowing past. In this way, the fluid flowing past is slowed down, consequently the fluid chooses to Example, the path of lower resistance and flows through the flow generator 2 in the suction jacket device 10, which increases the power output of the flow generator 2.

In particular, the second body can correspond to the flow generator 2 or the suction shroud device 10 .

The computing device 20 is arranged upstream of a flow inlet 4 of the flow generator 2 . while showing Figure 4A that the grid elements 21 can be arranged parallel to one another, for example.

In addition, in particular Figure 4B shown that the first ends 22 are oriented at an acute angle with respect to the flow direction A. In particular, the acute angle is defined in an angular range of approximately 1° to approximately 45°.

In addition, the flow power plant 1 can include a front body 5 . In particular, the first body can correspond to the front body 5 . The front body 5 is arranged, for example, upstream of the flow generator 2 and connected to the flow generator 2 . Alternatively or additionally, the front body 5 can be connected to the suction jacket device 10 . Thus, the front body can increase the stability of the flow power plant. Furthermore, the front body 5 can be designed, for example, as a buoyancy body to prevent the hydrodynamic power plant 1 from sinking. The front body can be made from a material or a combination of materials with a density of less than 997 kg/m ³ , for example. Alternatively or additionally, the front body can contain gas inclusions whose buoyancy effect is large enough to compensate for the total weight of the hydrodynamic power plant. In addition, the current power plant 1 can have an adjustable hydroplane 6 for regulating the swimming depth in the body of water. The controllable hydroplane is arranged, for example, in a front area with respect to the longitudinal direction A of the hydrodynamic power plant 1 . In particular, the hydroplane 6 can be designed, for example, as a fin that is aligned horizontally.

Furthermore, the operating voltage can preferably have a maximum of 60 V.

The flow power plant 1 can optionally have a fastening device 7 . The fastening device 7 is positioned, for example, in the front area, in particular on a nose, of the hydrodynamic power plant 1 . In particular, the fastening device 7 can be designed as an eyelet, hook, loop or the like. Thus, the flow power plant 1 can be attached to a fixed point in the area.

In the foregoing Detailed Description, various features have been grouped together in one or more examples to improve the rigor of presentation. However, it should be understood that the above description is merely illustrative and in no way restrictive. It is intended to cover all alternatives, modifications, and equivalents of the various features and embodiments. Many other examples will be immediately and immediately apparent to those skilled in the art in view of the above description.

The exemplary embodiments were selected and described in order to be able to present the principles on which the invention is based and its possible applications in practice in the best possible way. This allows professionals to Invention and its various embodiments in relation to the intended use optimally modify and use. In the claims and the description, the terms "including" and "having" are used as neutral terms for the corresponding terms "comprising". Furthermore, the use of the terms "a", "an" and "an" should not fundamentally exclude a plurality of features and components described in this way.

Reference List

1

flow power plant

2

flow generator

3

rotor

4

flow inlet

5

front body

6

dive planes

7

fastening device

10

suction jacket device

11

flow inlet port

12

flow outlet port

13

Shell housing segments (elastic 13A)

14

spring device

15

actuator

16

overlap area

17

outside

18

flow deflection device

20

computing device

21

grid elements

22

first end

23

second end

24

cavity

25

Distance

A

flow direction/longitudinal direction

B

transverse direction

Claims (15)

Computing device (20) for a kinetic flow power plant (1), with:
a plurality of grid elements (21) which extend along a flow direction (A) from a first body (5) to a second body (2; 10), the plurality of grid elements (21) each having a first end (22) at the first body (5) and having a second end (23) attached to the second body (2; 10) and bent such that they surround a cavity (24) together with the first and second bodies. Computing device according to Claim 1, in which a distance (25) between the plurality of grid elements (21) is in each case a maximum of 10 mm. A computing device according to claim 1 or 2, wherein the plurality of lattice elements (21) have a substantially quadrangular cross-section. 4. The computing device of claim 3, wherein the quadrilateral cross section has a width to height aspect ratio of at least 2. Computing device according to at least one of the preceding claims, wherein the plurality of grid elements (21) are arranged parallel to one another. Computing device according to at least one of the preceding claims, wherein the plurality of grid elements are arranged so laterally overlapping relative to one another that the computing device (20) consists of a Angular range of about 5 ° to about 175 ° in relation to the flow direction (A) considered having a closed optical barrier. Computing device according to at least one of the preceding claims, wherein at least one of the plurality of grid elements (21) has a varying width and/or height along its longitudinal extent from the first to the second end (22, 23). Computing device according to at least one of the preceding claims, wherein the cavity (24) surrounded by the plurality of grid elements (21) is egg-shaped, conical, spherical or the like. Computing device according to at least one of the preceding claims, wherein the first ends (22) are aligned at an acute angle with respect to the flow direction (A), in particular in an angular range of 1° to 45°. Computing device according to at least one of the preceding claims, wherein the plurality of grid elements (21) are designed as metal strips or rods. Kinetic flow power plant (1) with: a flow generator (2); a suction shroud device (10) which is arranged downstream of the flow generator (2) along a flow direction (A) and whose flow inlet opening (11) corresponds to the external dimensions of the flow generator (2); and a computing device (20) according to any one of the preceding claims, which is arranged upstream of a flow inlet (4) of the flow generator (2). Flow power plant according to Claim 11, further comprising a front body (5) which is arranged upstream of the flow generator (2) and is connected to the flow generator (2) and/or the suction shroud device (10). Flow power plant according to claim 12, wherein the first body corresponds to the front body (5) and the second body to the flow generator (2) or the suction jacket device (10). Flow power plant according to one of Claims 11 to 13, further comprising an adjustable hydroplane (6) for regulating the swimming depth in the body of water, which is arranged in an edge region in relation to the longitudinal direction (A) of the flow power plant (1). Flow power plant according to one of Claims 11 to 14, in which the front body (5) is designed as a buoyancy body to prevent the flow power plant (1) from sinking.

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