초록 ▼

The invention relates to a hydropower plant including a water turbine submerged in a water current, A grating is located adjacent the water turbine. According to the invention the grating is arranged to guide the water flow in the water current such that the velocity of the water between the grating

The invention relates to a hydropower plant including a water turbine submerged in a water current, A grating is located adjacent the water turbine. According to the invention the grating is arranged to guide the water flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform. The invention also relates to a use of the hydropower plant for generating electric energy for supply to an electric network. Further the invention relates to a method for operating a hydropower plant.

대표청구항 ▼

1. A method for operating a hydropower plant comprising the steps of: exposing a submerged water turbine to a wafer flow in a watercourse such that the water turbine rotates at a speed in a range of 0.5-50 rpm, the water turbine having a plurality of vanes extending in parallel to a rotational axis

1. A method for operating a hydropower plant comprising the steps of: exposing a submerged water turbine to a wafer flow in a watercourse such that the water turbine rotates at a speed in a range of 0.5-50 rpm, the water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms; andproviding a grating adjacent to the water turbine to prevent objects from flowing in the water from reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars forming gaps between each other, the cross section of a bar perpendicular to the longitudinal extension thereof having a length defined as the distance between a nose point where the water flow reaches the bar and a tail point where the water flow leaves the bar, having a bar width measured perpendicular to said length, and having a guiding direction defined as the direction of said length,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine, andwherein the grating varies with respect to at least one of the parameters; said length, said width, said guiding direction, the area of said cross section, and the profile of said cross section such that said at least one parameter varies from one bar to another for at least some bars, and such that said at least one parameter varies along the longitudinal extension of one bar. 2. A method for operating a hydropower plant comprising the steps of: exposing a submerged water turbine to a wafer flow in a watercourse such that the water turbine rotates at a speed in a range of 0.5-50 rpm, the water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms; andproviding a grating adjacent to the water turbine to prevent objects from flowing in the water from reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars defining gaps between each other, each gap forming a gap width,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine, andwherein the gap width varies from one gap to another for at least one of some gaps and varies along the longitudinal extension of one gap. 3. A method for operating a hydropower plant comprising the steps of: exposing a submerged water turbine to a wafer flow in a watercourse such that the water turbine rotates at a speed in a range of 0.5-50 rpm, the water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms; andproviding a grating adjacent to the water turbine to prevent objects from flowing in the water from reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars defining gaps between each other,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine,wherein at least some of the bars have different distance than other bars to a plane through the axis of the water turbine, which plane is perpendicular to the water flow, such that centrally located bars have a longer distance to said plane than laterally located bars, andwherein the location of the grating is defined in relation to a tangential plane through the outer periphery of the water turbine, the tangential plane being parallel to the plane through the rotational axis of the water turbine such that the grating is located on the side of the tangential plane that is located opposite to the plane through the rotational axis. 4. A hydropower plant comprising: a water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms, the water turbine being configured to rotate in a range of 0.5-50 rpm submerged in a water current; anda grating located adjacent the water turbine, the grating configured to prevent objects from flowing in the water from reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars defining gaps between each other, the cross section of a bar perpendicular to the longitudinal extension thereof having a length defined as the distance between a nose point where the water flow reaches the bar and a tail point where the water flow leaves the bar, having a bar width measured perpendicular to said length, and having a guiding direction defined as the direction of said length,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine, andwherein the grating varies with respect to at least one of the parameters; said length, said width, the area of said cross section, and the profile of said cross section such that said at least one parameter varies from one bar to another for at least some bars, and such that said at least one parameter varies along the longitudinal extension of one bar. 5. A hydropower plant according to claim 4 wherein the axis of the water turbine has a direction that is mainly perpendicular to the water flow, thereby defining a first half of the water turbine that rotates with the water and a second half that rotates against the water. 6. A hydropower plant according to claim 4 wherein the longitudinal extension of the bars is substantially parallel to the axis of the water turbine. 7. A hydropower plant according to claim 4 wherein the grating has a first set of bars and a second set of bars arranged such that the bars of the first set cross the bars of the second set. 8. A hydropower plant according to claim 4 wherein the grating is adjustable in respect to its guiding properties. 9. A hydropower plant according to claim 4 wherein a shaft of the water turbine is vertical. 10. A hydropower plant according to claim 9 wherein the shaft is supported by a foundation on the bed of the watercourse and the grating is supported by the same foundation as the shaft. 11. A hydropower plant according to claim 4 wherein the water turbine is arranged for a rotation in the range of 2 to 20 rpm. 12. A hydropower plant according to claim 4 wherein the plant includes a plurality of water turbines and that each turbine has an individual grating. 13. A hydropower plant according to claim 4 wherein the plant includes a plurality of water turbines and that a grating is in common for at least some of the water turbines. 14. A use of a hydropower plant according to claim 4 for generating electric energy for supply to an electric network. 15. A hydropower plant comprising: a water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms, the water turbine being configured to rotate in a range of 0.5-50 rpm submerged in a water current; anda grating located adjacent the water turbine, the grating configured to prevent objects from flowing in the water form reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars defining gaps between each other, each gap forming a gap width,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine, andwherein the gap width varies from one gap to another for at least some gaps and varies along the longitudinal extension of one gap. 16. A hydropower plant comprising: a water turbine having a plurality of vanes extending in parallel to a rotational axis of the water turbine and connected to a shaft of the turbine via arms, the water turbine being configured to rotate in a range of 0.5-50 rpm submerged in a water current; anda grating located adjacent the water turbine, the grating configured to prevent objects from flowing in the water from reaching the turbine,wherein the grating is configured to guide the flow in the water current such that the velocity of the water between the grating and the water turbine becomes non-uniform, such that the mean velocity of the water reaching the first half is larger than the mean velocity of the water reaching the second half, and such that the velocity profile of the water reaching the water turbine has a maximum in the water tangentially reaching said first half and a minimum in the water tangentially reaching said second half,wherein the grating includes a plurality of bars defining gaps between each other,wherein the gaps between the bars of the grating are substantially smaller than a tangential distance between adjacent vanes of the water turbine,wherein at least some of the bars have different distance than other bars to a plane through the rotational axis of the water turbine, which plane is perpendicular to the water flow, such that centrally located bars have a longer distance to said plane than laterally located bars, andwherein the location of the grating is defined in relation to a tangential plane through the outer periphery of the water turbine, the tangential plane being parallel to the plane through the rotational axis of the water turbine such that the grating is located on the side of the tangential plane that is located opposite to the plane through the rotational axis.