RU2483968C2 - Sea floating power plant - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to ship building, more specifically - to floating power generation facilities. Sea floating power plant (SFPP) includes body in the form in plane of isosceles triangle at corners of which pillars with wind power plants (WPP) at their top ends are located; control house and anchor positioning system. In submerged parts of its body, through cuts are made, and freeboard height constitutes at least 0.01 of outer length of its board. WPP pillars are made as masts and are installed on upper deck. The height of WPP location on masts is not less than sum of its blade length and the greatest height of wave possible in corresponding aquatic area. Also, SFPP is fitted with equipment for electric power generation using wave energy, sea current energy, solar energy.

EFFECT: invention allows for lowering weight of structures and SFPP positioning system while increasing electric energy output and improving operation safety due to higher initial stability.

7 cl, 3 dwg

Description

The invention relates to the field of shipbuilding, and more specifically to means for generating electricity, and relates to the issue of providing electricity to consumers in energy-deficient regions.

Known marine floating wind farm (IPC F03D 11/04 with priority dated 08.03.2001, WO 02/073032 A1), which is a hollow semi-submersible column with connecting elements, one of which is rigidly or softly connected to a single-point floating or stationary mooring berth or turret. The columns are equipped with towers with wind power units (VEA) located on them, the number of which can be changed to increase the volume of generated electricity, and the arrangement of which reduces the occurrence of the mutual influence of turbulent flows of these VEA - a prototype.

The specified construction has a number of disadvantages, which include:

- high cost due to the presence of a mooring berth or turret;

- significant forces from the current and wave drift caused by a significant amount of columns and connecting elements immersed in water, and, accordingly, the efforts of anchor winches and lines:

- low initial stability due to the cross-sectional area of the columns crossing the waterline;

- large draft, which impedes the construction, moving and operation of the structure;

- the inability to use other types of renewable energy sources: excitement, currents and the sun.

The objective of the invention is to reduce the cost by reducing the metal consumption, the forces from the flow and wave drift with a simultaneous increase in the amount of generated energy and increase the initial stability.

To do this, at a marine floating power plant (MPES), which includes a body with the shape of a hollow isosceles triangle in plan, at the corners of which there are supports with VEA located at their upper ends, control wheelhouse and anchor retention system, through cuts are made in the underwater parts of its body, and the freeboard height is at least 0.01 of the outer length of its side. Moreover, VEA supports are made in the form of masts and are located on the upper deck, while the height of the VEA on the masts is not less than the sum of the length of their blades and the greatest wave height possible in the corresponding water area.

In this case, the length of the through cut-outs of the underwater part of the hull exceeds 0.5 of the outer length of its side, and their height is at least 0.2 of its draft.

In addition, MPES is equipped with equipment for generating electricity through the use of wave energy, including wave floats and a hydraulic motor with an electric generator connected to the specified floats by a high pressure pipeline. Moreover, the wave floats are made and installed on board with the possibility of their rise above the wave of the water area.

At the same time, MPES has an installation for generating electricity through the use of sea current energy, including underwater generators rotating under the action of the current and located outside the zone of action of wave floats and anchor retention systems.

In addition, MPES is equipped with an installation for generating electricity by using solar energy, including solar panels installed on an additional deck located above its upper deck at a level exceeding the highest wave height of the corresponding water area.

At the same time, wind and underwater generators, wave and solar installations are equipped and connected by cables to the cabin for processing and subsequent transmission of electricity to the shore network via a cable consisting of surface, underwater and underground sections.

The implementation of through cutouts in the underwater parts of the hull provides a reduction in the forces from the current and wave drift, and, consequently, the force of the anchor retention system, as well as the weight of the hull and systems.

The dimensions of the cutouts are taken from the conditions for ensuring the buoyancy and stability of the MPES, as well as the strength of the support of the supports under the wind turbine and underwater generators.

The freeboard height in quiet water is taken from the condition of ensuring the safe operation of temporary personnel performing repair and replacement of MPES equipment, as well as reducing the weight of the hull and applicants of the center of gravity (CT).

The implementation of VEA supports in the form of masts and their placement on the upper deck of MPES allow, in comparison with the columns in the prototype, to significantly reduce their diameter, weight and cost.

Performing a mast height of not less than the sum of the highest wave height of the water area and the length of the VEA blades, at which the contact of the waves with the VEA blades during operation is practically excluded, reduces the weight, cost and applicability of the Masts of the mast, as well as simplify the maintenance of the VEA.

To limit the costs of manufacturing and repairing wave floats, only the necessary minimum of parts are in the water, and in the wheelhouse there is a hydraulic motor, an electric generator and computer control of wave floats. To avoid damage to the floats during intense waves provided for their rise above the waves.

Wind and wave installations can act both simultaneously and separately.

Underwater generators using the energy of sea currents are located under the hull at a depth of at least the sum of the length of their blades and the maximum half-wave height possible in the corresponding water area.

The invention is illustrated by drawings, where figure 1 schematically shows the proposed marine floating power plant (top view without additional deck), figure 2 is a front view and figure 3 is a view along arrow A (see figure 1) on the wave float.

On the upper deck of the hull 1 of the marine floating power plant there are masts 2 with wind power units 3 (figure 2), installed so that the turbulent flows caused by these units do not collide with each other. These units have a diameter of obturation 4 (figure 2) and a surface section of cable 5 for transmitting electricity to the control cabin 6.

The housing 1 is connected to an anchor retention system having anchor lines 8 with anchors of increased holding force 9, and through the clutch 10 along the underwater 11 and underground sections 12 of the cable with the shore electrical network (figure 2). The housing 1 has through cutouts 13 (FIGS. 2, 3) with a length l _b exceeding 0.5 of the outer length of its side and a height d _{b of} at least 0.2 of its draft, as well as a freeboard F from the waterline 14 (FIG. .2, 3).

The height of the masts 2 is chosen so that the diameter of the sweeping 4 does not touch the highest wave height possible in the water area h _w , and the diameter of the masts - so as to ensure the perception of forces and moments from the wind, as well as inertial loads caused by vibrations of the MPES on the waves.

MPES is equipped with equipment for generating electricity through the use of wave energy, including wave floats 15 connected to the high pressure pipe 7 using a pipe 16 passing through the bracket 17, which is connected to the hydraulic cylinder 18 and the hinge 19 at its upper end (figure 3) . The working fluid, mainly hydraulic oil 20 from each hydraulic cylinder 18 has the possibility of flowing through the main pipeline 7 (Fig. 3) to the hydraulic motor 21 connected to the electric generator 22 (Fig. 1), which are located in the control wheel 6. Wave floats 15 are made and installed with the possibility of their rise above the waves. For their rise above the waves to the required angle α with intense waves provided brackets 17 with hinges 19 (figure 3).

In addition, MPES is equipped with an installation for generating electricity through the use of sea current energy, in which underwater generators 23 with a diameter of 24 sweeping 24 blades 26 are located on the brackets 25 under the housing 1 so as not to interfere with the wave floats 15 and anchor lines 8, and the length the brackets 25 is at least the sum of half the highest wave height possible in the water area and the length of the blade 26. On the brackets 25 the cables 27 are laid in the control cabin 6.

In addition, MPES has an installation for generating electricity through the use of solar energy, including solar panels 29 located on the auxiliary deck 28 located above waterline 14 at a height of h _w . Deck 28 is located on pillers 30 that can withstand external loads, solar panels are connected to wheelhouse 6 surface cable 31.

The control wheelhouse 6 for processing energy received from the aforementioned electrical installations 3, 15, 23 and 29 is connected to a cable 11 for transmitting electricity to the shore network via cable 12.

The work of MPES is as follows. In light winds, the rotation of the VEA 3 blades on the masts 2 begins and the generated electricity is transmitted via cable 5 to the control cabin 6, which contains the necessary equipment (not shown in the figures) and located on the upper deck of the hull 1. When the maximum permissible wind speed is reached, the VEA are stopped to avoid damage to blades, gears and generators (not shown in the figures). The position of the MPES in the survival mode at a given place of operation is ensured by the interaction of anchor lines 8 and anchors of increased holding force 9. The reduction of forces from the current and wave drift, which determine the loads on the anchor lines and anchors, is ensured by the 13 cutouts 13 necessary (indicated ) sizes.

The strength of the VEA blades is ensured by the fact that their sweeping diameter 4 does not touch the wave of the highest height possible in the water area.

When the waves are weak, the wave floats 15 mounted on the brackets 17 begin to move. Due to the movement of the floats 15, the hydraulic cylinder 18 pushes the working fluid (hydraulic oil) 20 through the pipe 16 located on the bracket 17 into the main pipe 7, which delivers it to the hydraulic pump 21, a rotating electric generator 22 (shown in FIG. 1 conventionally) placed in the control wheelhouse 6.

With an increase in the intensity of the waves above a predetermined one, in order to avoid damage to the floats 15, the pipeline 16 and the hydraulic cylinder 18, the hinges 19 turn and raise the indicated equipment to the required height (at an angle α).

Underwater generators 23 with a sweeping diameter 24, mounted under the housing 1 on the brackets 25, begin to work at a sufficient flow rate. The generated electricity via cables 27 is transferred to the control cabin 6.

Electricity generated by solar panels 29 located on deck 28 mounted above hull 1 on pillers 30 is transmitted via cables 31 to control room 6.

After processing in control cabin 6, electricity from wind and underwater generators, wave and solar installations is transmitted to the coastal network through the clutch 10 through the underwater 11 and underground 12 cable sections.

Testing the model of the proposed power plant on a wave showed that the amplitudes and accelerations of various types of rolling are significantly lower than on ships and floating platforms of close displacement and size.

The performed technical and economic calculations confirmed the possibility of ensuring the cost of electricity below tariffs in a number of regions of Russia, as well as obtaining acceptable investment indicators during the construction of the proposed power plant.

The proposed solution allows to reduce the cost of a marine floating power plant by reducing the weight of structures and containment systems while increasing the amount of generated electricity and increasing operational safety due to greater initial stability, which distinguishes it from the prototype.

Claims (7)

1. Marine floating power plant, comprising a hull with the shape of a hollow isosceles triangle in plan, at the corners of which there are supports with wind power units located at their upper ends, a control cabin and an anchor retention system, characterized in that through cuts are made in the underwater parts of its hull, and the freeboard height is not less than 0.01 of the outer length of its side, and the supports of wind power units are made in the form of masts and are located on the upper deck, and the height of the wind energy units on the masts is not less than the sum of the length of their blades and the greatest wave height possible in the corresponding water area. 2. Marine floating power station according to claim 1, characterized in that the length of the through cut-outs of the underwater part of the hull exceeds 0.5 of the outer length of its side, and their height is at least 0.2 of its draft. 3. The marine floating power plant according to claim 1, characterized in that it is equipped with equipment for generating electricity through the use of wave energy, including wave floats and hydraulic cylinders that provide the operation of a hydraulic motor connected to them by a main pipeline. 4. Marine floating power plant according to claim 3, characterized in that the wave floats are made and installed on board with the possibility of their rise above the wave of the water area. 5. Marine floating power station according to claim 1, characterized in that it is equipped with an installation for generating electricity through the use of sea current energy, including subsea generators that rotate under the action of the current and are located outside the range of wave floats and anchor retention systems under the body on depth of at least the sum of the length of their blades and half of the greatest wave height possible in the corresponding water area. 6. The marine floating power plant according to claim 1, characterized in that it is equipped with an installation for generating electricity through the use of solar energy, including solar panels located on an additional deck located above its upper deck at a level exceeding the highest wave height possible in relevant water area. 7. Marine floating power plant according to any one of claims 1 to 6, characterized in that the cabin for processing energy received from wind and underwater generators, wave and solar installations is connected to a cable for transmitting electricity to the shore network.

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