WO2021248369A1 - 大型潮流能发电装置及其总成平台 - Google Patents

大型潮流能发电装置及其总成平台 Download PDF

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Publication number
WO2021248369A1
WO2021248369A1 PCT/CN2020/095387 CN2020095387W WO2021248369A1 WO 2021248369 A1 WO2021248369 A1 WO 2021248369A1 CN 2020095387 W CN2020095387 W CN 2020095387W WO 2021248369 A1 WO2021248369 A1 WO 2021248369A1
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WIPO (PCT)
Prior art keywords
force
power generation
fixed
assembly platform
tidal current
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PCT/CN2020/095387
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English (en)
French (fr)
Inventor
林东
朱福巍
Original Assignee
杭州林黄丁新能源研究院有限公司
杭州林东新能源科技股份有限公司
浙江舟山联合动能新能源开发有限公司
舟山林东潮流发电有限公司
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Application filed by 杭州林黄丁新能源研究院有限公司, 杭州林东新能源科技股份有限公司, 浙江舟山联合动能新能源开发有限公司, 舟山林东潮流发电有限公司 filed Critical 杭州林黄丁新能源研究院有限公司
Priority to CA3186966A priority Critical patent/CA3186966A1/en
Priority to JP2022575794A priority patent/JP2023529902A/ja
Priority to KR1020227043595A priority patent/KR20230009976A/ko
Priority to US18/009,934 priority patent/US20230151792A1/en
Priority to PCT/CN2020/095387 priority patent/WO2021248369A1/zh
Priority to EP20939792.6A priority patent/EP4166779A4/en
Publication of WO2021248369A1 publication Critical patent/WO2021248369A1/zh

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B13/00Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates
    • F03B13/12Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy
    • F03B13/26Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using tide energy
    • F03B13/264Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates characterised by using wave or tide energy using tide energy using the horizontal flow of water resulting from tide movement
    • EFIXED CONSTRUCTIONS
    • E02HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
    • E02BHYDRAULIC ENGINEERING
    • E02B17/00Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor
    • EFIXED CONSTRUCTIONS
    • E02HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
    • E02BHYDRAULIC ENGINEERING
    • E02B9/00Water-power plants; Layout, construction or equipment, methods of, or apparatus for, making same
    • E02B9/08Tide or wave power plants
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B11/00Parts or details not provided for in, or of interest apart from, the preceding groups, e.g. wear-protection couplings, between turbine and generator
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B3/00Machines or engines of reaction type; Parts or details peculiar thereto
    • F03B3/04Machines or engines of reaction type; Parts or details peculiar thereto with substantially axial flow throughout rotors, e.g. propeller turbines
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B3/00Machines or engines of reaction type; Parts or details peculiar thereto
    • F03B3/12Blades; Blade-carrying rotors
    • F03B3/128Mounting, demounting
    • EFIXED CONSTRUCTIONS
    • E02HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
    • E02BHYDRAULIC ENGINEERING
    • E02B17/00Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor
    • E02B2017/0056Platforms with supporting legs
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B17/00Other machines or engines
    • F03B17/06Other machines or engines using liquid flow with predominantly kinetic energy conversion, e.g. of swinging-flap type, "run-of-river", "ultra-low head"
    • F03B17/061Other machines or engines using liquid flow with predominantly kinetic energy conversion, e.g. of swinging-flap type, "run-of-river", "ultra-low head" with rotation axis substantially in flow direction
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2220/00Application
    • F05B2220/30Application in turbines
    • F05B2220/32Application in turbines in water turbines
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2220/00Application
    • F05B2220/70Application in combination with
    • F05B2220/706Application in combination with an electrical generator
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2240/00Components
    • F05B2240/90Mounting on supporting structures or systems
    • F05B2240/91Mounting on supporting structures or systems on a stationary structure
    • F05B2240/916Mounting on supporting structures or systems on a stationary structure with provision for hoisting onto the structure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2240/00Components
    • F05B2240/90Mounting on supporting structures or systems
    • F05B2240/97Mounting on supporting structures or systems on a submerged structure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2260/00Function
    • F05B2260/04Deployment, e.g. installing underwater structures
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F05INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
    • F05BINDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
    • F05B2260/00Function
    • F05B2260/96Preventing, counteracting or reducing vibration or noise
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/20Hydro energy
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/30Energy from the sea, e.g. using wave energy or salinity gradient
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/72Wind turbines with rotation axis in wind direction

Definitions

  • the invention belongs to the field of tidal energy power generation, and in particular relates to a large-scale tidal energy power generation device and an assembly platform thereof.
  • Ocean energy (including tidal energy, wave energy, temperature difference energy, salinity difference energy, ocean current energy, etc.) is a clean and pollution-free renewable energy with abundant reserves and wide distribution, which has excellent development prospects and value.
  • energy is increasingly scarce, the greenhouse effect is becoming more and more serious, and energy needs to be low-carbon. Therefore, clean energy such as wind energy and ocean energy is the development direction of future energy.
  • clean energy power generation equipment in addition to the relatively mature use of wind energy, the utilization of ocean energy is still in its infancy, and there is no universal and mature equipment, and the power generation power is lower than that of other energy sources.
  • the most important thing is that the existing ocean energy power generation devices are much higher than the cost of other energy generation in terms of manufacturing cost, installation cost or maintenance cost. This has become the biggest obstacle restricting the commercial application and promotion of ocean energy power generation devices. .
  • the maximum installed power of a single unit of a wind power generation device that uses offshore wind to generate electricity can reach 5MW. It is to fix a tower on the seabed, and then the wind generator is fixed on the top of the tower and above the sea surface to collect wind energy to generate electricity.
  • the diameter of the lower end of the tower is 6.242m
  • the diameter of the uppermost end is 4.170m
  • the average diameter of the tower is 5.206m
  • the height of the entire tower is 96m.
  • Such a tower which weighs 439 tons, is expensive to construct and install. Because of the high cost, it cannot be converted into real economic value. Even if you want to use it on a large scale, it is discouraged by the high cost.
  • Traditional tidal current power generation devices usually adopt two fixed methods, one is floating fixed, that is, floating in the sea through a floating bed and fixed on the seabed or both sides by steel cables, and the other is fixed on the seabed, that is, through a fixed
  • the fixed pile is directly fixed on the seabed. Since floating stationary still mainly uses wave energy for power generation, the power generation is not high compared to deep tidal energy, and the scale of the generator that can be suspended is small, so the economic value is small, and it is gradually abandoned in practical applications.
  • the second type of seabed fixed type is the fixed method adopted by the existing tidal current power generation devices that are actually put into practical application.
  • the largest single-unit installed power of the power generation module that is actually put into operation of the existing tidal current power generation device is 2MW.
  • the traditional tidal current power generation device is similar to the offshore wind power generation device, and it is also directly fixed to the seabed through a fixed pile. Due to the huge impact of seawater, the fixed pile must have a large enough diameter to resist the bending moment. The larger the diameter of the fixed pile, the higher the pile driving cost.
  • a fixed pile of a specific diameter has an upper limit for its bearing capacity, so correspondingly, it can only carry horizontal-axis hydro-generators within a certain scale.
  • Fixed piles cannot be made unlimited in terms of cost or technology, and this also causes the installed power of a single horizontal-axis hydro-generator to fail to break through.
  • the present invention provides a large-scale tidal current power generation device and an assembly platform thereof.
  • the present invention provides an assembly platform for a large tidal current power generation device, in which at least one horizontal axis hydroelectric generator is installed.
  • the assembly platform of the large tidal current power generation device includes at least four fixed piles, at least two force blocking members, at least two force support members and brackets. At least four fixed piles are connected by brackets to form an installation space. At least one horizontal-axis turbine generator is installed in the installation space. One end of each fixed pile is fixed on the seabed and the other end extends above the water surface.
  • the four fixed piles are arranged in two rows along the direction of water flow, and at least two fixed piles in each row are arranged in sequence along the direction of water flow.
  • At least two force blocking members are respectively fixed on the corresponding fixed piles or brackets and are located on the left and right sides of the horizontal axis turbine generator below the water surface along the water flow direction.
  • One end of the at least two force supporting members are respectively installed on the left and right sides of the horizontal axis turbine generator along the direction of the water flow, and the other end respectively abuts on the corresponding force blocking member to resist the impact of the water flow on the horizontal axis turbine generator. The impact.
  • the assembly platform further includes at least two sets of shock-absorbing devices, and each set of shock-absorbing devices is arranged between the force supporting member and the force blocking member.
  • the assembly platform has at least two guide grooves, which are respectively arranged on the corresponding fixed piles or brackets and are located on the left and right sides of the horizontal axis turbine generator along the water flow direction.
  • One end of the groove is located above the water surface, and the other end leads to below the water surface, and at least two force-bearing blocking members are respectively fixed to the other end of the corresponding guide groove.
  • the assembly platform further includes at least two sets of fence guide grooves for installing or fixing the fence, and the at least two sets of fence guide grooves are respectively arranged upstream and downstream of the horizontal axis hydroelectric generator On both sides, each set of fence guide troughs lead from above the water surface to below the water surface.
  • the assembly platform further includes at least one man-passing pipe, one end of the at least one man-passing pipe is located above the water surface, and the other end is connected to the horizontal-axis hydro-turbine generator or one of the force supports A piece or a force-bearing blocking piece, so that people can reach below the water surface through at least one pass-through pipe for maintenance or fixing operations.
  • the assembly platform further includes at least one blower and one vent pipe.
  • the vent pipe can be fixedly or detachably arranged along the inside or outside the passage. The vent pipe From above the water surface to below the water surface so that the work area under the water can be exchanged.
  • the assembly platform further includes at least one pump and at least one drainage pipe, and the drainage pipe can be fixedly or detachably arranged along the inside or outside the passage.
  • the drainage pipe runs from above the water surface to below the water surface, and the water pump pumps the accumulated water in the working area below the water surface and discharges it above the water surface through the drainage pipe.
  • the assembly platform further includes at least two fixed component boxes, each fixed component box is arranged corresponding to the force blocking member and has a hollow structure, and personnel can enter the inside of the fixed component box working.
  • each fixing component box has a sealing device and a fixing component
  • the fixing component includes at least one fixing bolt or at least one jack
  • the sealing device is correspondingly provided at the fixing component
  • a side plate is provided on one side of each row of fixed piles facing the horizontal-axis turbine generator.
  • each fixed pile of the assembly platform is provided with a concrete protection device in an area above the lowest tide line.
  • the large-scale tidal current power generation device includes the fence as provided in the fourth aspect of the present invention.
  • the present invention also provides a large-scale tidal current power generation device, including the assembly platform according to any one of the embodiments of the first aspect, at least one horizontal axis hydroelectric generator, and at least one suspension support column. At least one horizontal axis water turbine generator is detachably installed in the assembly platform. At least one suspension support column is a closed hollow structure, one end of the suspension support column is located above the water surface, and the other end of the suspension support column is connected to the horizontal axis turbine generator or the force blocking member or the force support member, so that people can pass through the suspension support column Reach below the water surface for maintenance or fixing operations.
  • the large-scale tidal current power generation device further includes at least one connector, and the at least one connector horizontally or longitudinally connects an end of the suspension support column above the water surface and the assembly platform.
  • the assembly platform includes at least two fixed component boxes, each fixed component box is arranged corresponding to the force blocking member and has a hollow structure, and the number of suspension support columns is at least two , The other ends of the at least two suspension support columns are respectively connected to the corresponding fixed component box, so that personnel can reach the inside of the fixed component box through the suspension support column.
  • the number of suspension support columns is three, and the other ends of the two suspension support columns are respectively connected to the force blocking member or the force support located on both sides of the horizontal-axis turbine generator.
  • the other end of the other suspension support column is connected to the horizontal-axis turbine generator, and the ends of the three suspension support columns above the water surface are connected to each other.
  • the large-scale tidal current power generation device includes the fence as provided in the fourth aspect of the present invention.
  • the present invention also provides a large-scale tidal current power generation device, including:
  • each assembly platform includes at least four fixed piles, the at least four fixed piles are connected by a bracket to form an installation space, one end of each fixed pile is piled and fixed to the seabed, and the other One end extends above the water surface, the at least four fixed piles are arranged in two rows along the water flow direction, and at least two fixed piles in each row are arranged along the water flow direction;
  • At least three horizontal-axis hydraulic generators, and at least one horizontal-axis hydraulic generator is detachably installed in the installation space of each assembly platform;
  • the at least two assembly platforms are arranged left and right along the direction of water flow, and the interval between the two assembly platforms matches the diameter of the impeller of a horizontal-axis hydro-generator, so that at least one additional horizontal-axis hydraulic wheel
  • the generator can be installed between two assembly platforms.
  • each assembly platform includes at least two force blocking members and at least two force support members, and the at least two force blocking members are respectively fixed to the corresponding fixed piles or
  • the bracket is located on the left and right sides of the horizontal axis turbine generator below the water surface along the water flow direction.
  • One end of the at least two force supporting members are respectively installed on the left and right sides of the horizontal axis turbine generator along the direction of the water flow, and the other end respectively abuts on the corresponding force blocking member to resist the impact of the water flow on the horizontal axis turbine generator. The impact.
  • the assembly platform further includes at least two sets of shock-absorbing devices, and each set of shock-absorbing devices is arranged between the force supporting member and the force blocking member.
  • the assembly platform has at least two guide grooves, which are respectively provided on the corresponding fixed piles or brackets and are located on the left and right sides of the horizontal axis turbine generator along the water flow direction.
  • One end of the groove is located above the water surface, and the other end leads to below the water surface, and at least two force-bearing blocking members are respectively fixed to the other end of the corresponding guide groove.
  • each assembly platform further includes at least two sets of fence guide grooves for installing or fixing fences, and the at least two sets of fence guide grooves are respectively arranged on the horizontal axis water wheel to generate electricity.
  • each set of fence guide troughs lead from above the water surface to below the water surface.
  • each assembly platform includes at least one man-passing pipe, one end of the at least one man-passing pipe is located above the water surface, and the other end is connected to the horizontal axis hydraulic turbine generator or one of the force-receiving pipes.
  • the supporting member or the force-bearing blocking member enables a person to reach below the water surface through at least one man-passing pipe to perform maintenance or fixing operations.
  • each assembly platform includes at least one blower and one ventilation pipe, and the ventilation pipe can be fixedly or detachably arranged along the inside or outside the passage.
  • the ventilation pipe is passed from above the water surface to below the water surface so that the working area under the water surface can be exchanged for air.
  • each assembly platform includes at least one pump and at least one drainage pipe, and the drainage pipe can be fixedly or detachably run along or along the passageway.
  • the drainage pipe runs from above the water surface to below the water surface, and the water pump pumps the accumulated water in the working area below the water surface and discharges it above the water surface through the drainage pipe.
  • each assembly platform includes at least two fixed component boxes, each fixed component box is arranged corresponding to the force blocking member and has a hollow structure, and personnel can enter the fixed component box. Work internally.
  • each fixing component box has a sealing device and a fixing component
  • the fixing component includes at least one fixing bolt or at least one jack
  • the sealing device is correspondingly provided at the fixing component
  • a side plate is provided on one side of each row of fixed piles facing the horizontal-axis turbine generator.
  • each fixed pile of each assembly platform is provided with a concrete protection device in an area above the lowest tide line.
  • the tidal current power generation device further includes at least one suspension support column, the suspension support column is a closed hollow structure, one end of the suspension support column is above the water surface, and the other end of the suspension support column is connected to the horizontal
  • the shaft turbine generator or the force blocking member or the force support member enables people to reach below the water surface through the suspension support column to perform maintenance or fixing operations.
  • the large-scale tidal current power generation device further includes at least one connector, and the at least one connector horizontally or longitudinally connects the end of the suspension support column above the water surface and the assembly platform.
  • each assembly platform includes at least two fixed component boxes, each fixed component box is arranged corresponding to the force blocking member and has a hollow structure, and the number of suspended support columns is at least Two, at least the other ends of the two suspension support columns are respectively connected to the corresponding fixed component box, so that personnel can reach the inside of the fixed component box through the suspension support column.
  • the number of suspension support columns is three, and the other ends of the two suspension support columns are respectively connected to the force blocking members or force supports located on both sides of the horizontal-axis turbine generator.
  • the other end of the other suspension support column is connected to the horizontal-axis turbine generator, and the ends of the three suspension support columns above the water surface are connected to each other.
  • the large tidal current power generation device includes the fence as provided in the fourth aspect of the present invention.
  • the present invention also provides a tidal current power generation device, including at least two fences, which are respectively arranged on the upstream and downstream sides of the horizontal axis hydroelectric generator, and the width of each fence along the water flow direction is greater than or equal to 8 cm .
  • the tidal current power generating device includes the assembly platform according to any one of the embodiments of the first aspect or the second aspect of the present invention.
  • the tidal current power generation device includes the suspension support column as described in any embodiment of the second aspect of the present invention.
  • the tidal current power generating device adopts the tidal current power generating device as described in any embodiment of the third aspect of the present invention.
  • the present invention also provides a large-scale tidal current power generation device, including:
  • the horizontal axis hydraulic generator can be detachably placed in the assembly platform
  • At least two force-bearing blocking members are arranged on the assembly platform and located below the water surface;
  • At least two force-receiving supports one end of the two force-receiving supports are respectively installed on the left and right sides of the horizontal axis turbine generator along the water flow direction, and the other end is respectively abutted against the left and right sides of the assembly platform On the two force blocking members on the side to resist the impact force of the water flow on the horizontal-axis hydro-generator;
  • At least one human pipeline one end is connected to the interior of the horizontal axis turbine generator, the other end is above the water surface, or one end leads to the working area of the assembly platform below the water surface, and the other end leads above the water surface, so that people can enter Work in the working area below the water surface;
  • At least one blower At least one blower
  • vent pipe At least one vent pipe, the vent pipe can be fixed or detachably installed on the inside or outside of the access pipe, one end of the vent pipe leads above the water surface, and the other end leads below the water surface.
  • one end of the vent pipe leads above the water surface
  • the other end leads below the water surface.
  • the fifth aspect of the present invention includes at least one pump and at least one drain pipe.
  • the drain pipe can be fixedly or detachably installed on the inside or outside of the passageway. One end leads to above the water surface, and the other end leads to the working area below the water surface. When there is water leakage in the working area below the water surface, the water pump draws the internal water through the drain pipe and discharges it above the water surface to ensure the safety of equipment or workers. .
  • the large-scale tidal energy generating device includes the fence as described in any one of the embodiments of the fourth aspect of the present invention.
  • the present invention forms an installation space by connecting four fixed piles and brackets together, and then the horizontal-axis turbine generator is fixed in the installation space, instead of installing the horizontal-axis turbine generator as in the prior art
  • the use of steel is greatly reduced, and the manufacturing and installation costs are reduced.
  • the present invention can evenly transmit the thrust of the water flow received by the horizontal-axis turbine generator to both sides by arranging the force-receiving support members and the force-receiving blocking members located on both sides of the horizontal-axis hydraulic turbine generator, thereby dispersing it to the entire
  • the assembly platform enables the entire assembly platform to carry a single horizontal axis hydro-generator with greater power, which greatly reduces the power generation cost of the tidal current power generation device.
  • the horizontal axis hydroelectric generator of the present invention has a "fixed point" in the water, thus avoiding the horizontal axis hydroelectric generator in the prior art under the huge thrust of the water flow, which is easily damaged due to the vibration of the horizontal axis hydroelectric generator. problem.
  • the tidal current power generation device can be truly large-scaled, and the cost of tidal current power generation can be reduced to lower than that of thermal power generation, thereby realizing tidal current power generation.
  • Fig. 1 shows a top view of a large tidal current power generation device according to a first embodiment of the present invention.
  • Fig. 2 shows a side view of a large tidal current power generation device according to the first embodiment of the present invention.
  • Fig. 3 is a schematic cross-sectional view of a stressed support member and a stressed blocking member provided by the present invention in different embodiments.
  • Figure 4 is a schematic diagram of the installation of a large tidal current power generation device according to the first embodiment of the present invention.
  • Fig. 5 shows a partial top view of a large tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 6 shows a partial side view of a large tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 7 is a top view of the inner module of the large tidal current power generation device according to the second embodiment of the present invention.
  • Fig. 8 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 9 is a schematic diagram of the installation of a large tidal current power generating device according to a third embodiment of the present invention.
  • Fig. 10 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a fourth embodiment of the present invention.
  • Fig. 11 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a fifth embodiment of the present invention.
  • Fig. 12 is a top view of a large tidal current power generation device according to a sixth embodiment of the present invention.
  • Fig. 13 shows a top view of a large tidal current power generation device according to a seventh embodiment of the present invention.
  • Fig. 14 is a schematic diagram of a fence provided according to an eighth embodiment of the present invention.
  • Fig. 15 is a schematic diagram of a large-scale tidal current power generation device according to a ninth embodiment of the present invention.
  • Fig. 16 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a ninth embodiment of the present invention.
  • Fig. 17 is a schematic diagram of a large-scale tidal current power generation device according to a tenth embodiment of the present invention.
  • Fig. 1 shows a top view of a large tidal current power generation device according to a first embodiment of the present invention.
  • Fig. 2 shows a side view of a large tidal current power generation device according to the first embodiment of the present invention.
  • Fig. 3 is a schematic cross-sectional view of a force supporting member and a force blocking member provided according to the first embodiment of the present invention.
  • Figure 4 is a schematic diagram of the installation of a large tidal current power generation device according to the first embodiment of the present invention.
  • the circle on the right in Figure 2 is an enlarged schematic diagram of the mark on the left circle.
  • the large-scale tidal current power generation device includes an assembly platform 1 and at least one horizontal-axis hydraulic generator 2, and at least one horizontal-axis hydraulic generator 2 is installed on Assembly platform 1.
  • the assembly platform 1 includes at least four fixed piles 11, at least two force blocking members 12, at least two force support members 13, and a bracket 14.
  • One end of each fixed pile 11 is piled and fixed to the seabed F, and the other end extends above the water surface P.
  • At least four fixed piles 11 are connected into one body by brackets 14, and the four fixed piles 11 and bracket 14 surround together to form an installation space 15.
  • the four fixed piles 11 are arranged in two rows along the water flow direction D, and at least two fixed piles 11 in each row are arranged in order along the water flow direction D.
  • at least four fixed piles 11 are divided into two groups (ie, two rows), and each group includes at least two fixed piles 11.
  • the line connecting the cross-sections of at least two fixed piles 11 in each group through the center point is substantially parallel to the water flow direction D (some slight deviations may be allowed). Since each group of fixed piles 11 are arranged in a row parallel to the direction D of the water flow, the impact force of the water flow borne by the fixed piles 11 located downstream will be greatly reduced after being blocked by the fixed piles 11 located upstream.
  • the direction of the water flow is D
  • the direction of the water flow is D’.
  • the “left” and “right” mentioned in this article refer to the left and right sides relative to the direction of water flow. Specifically, when viewed from the direction shown in FIG. 1, that is, viewed from above the water surface, the two rows of fixed piles 11 are located on the left and right sides, respectively.
  • the bracket 14 includes a plurality of rigid rods, and each rigid rod is connected to two fixed piles 11.
  • the force borne by the entire assembly platform 1 is transmitted between the fixed piles 11 by the bracket 14 to be decomposed.
  • the bracket 14 at least four fixed piles 11 form a whole together, and the force received by a single fixed pile 11 can be effectively transmitted to other fixed piles 11, so that the force distribution of the entire assembly platform 1 is balanced.
  • the underwater part and the above water part of the fixed pile 11 are both provided with a bracket 14 for connection.
  • connection position and connection number of the bracket 14 can be set according to specific requirements.
  • each fixed pile 11 does not necessarily have to be installed completely perpendicular to the seabed F.
  • the fixed piles 11 located on the water-incoming side or the falling side ie the bottom and top as shown in FIG. 1 can be inserted into the seabed F obliquely.
  • the ability of each obliquely inserted fixed pile 11 to resist the impact force of water current is about 1.5 times that of the fixed pile installed vertically, that is, the fixed pile 11 installed obliquely can bear and disperse greater water impact force.
  • the assembly platform 1 of the large tidal current power generation device may include a total of eight fixed piles 11, the four fixed piles 11 are located on the left side of the horizontal axis hydroelectric generator 2, and the four fixed piles 11 are located on the horizontal axis.
  • the four fixed piles 11 on the left or right are arranged in sequence along the direction D of the water flow.
  • the present invention also does not make any limitation on the specific number of the fixed piles 11. In other embodiments, the number of fixed posts may be 4, 6, or 12.
  • the assembly platform 1 provided by the embodiment of the present invention can support a higher-power horizontal-axis hydro-generator 2, which increases the upper limit of the power of a single turbine impeller plus a single generator, thereby realizing the commercial promotion of tidal current power generation devices. And use.
  • each fixed pile 11 can be correspondingly reduced, thereby reducing the cross section of the fixed pile 11 blocking water flow, and increasing the utilization rate of the water flow of the horizontal axis turbine generator 2 to make the level The power generation efficiency of the shaft turbine generator 2 is improved.
  • the device can carry a maximum installed power of a single machine of 5 MW, but it requires fixed piles with a maximum diameter of more than 6 m to carry the load.
  • at least four fixed piles 11 and brackets 14 are formed as a whole to disperse the thrust of the received water flow.
  • Each fixed pile only needs to be 1.3m in diameter to carry the horizontal axis water with a single machine installed power of 5MW. Therefore, the diameter of the fixed pile can be greatly reduced. The difficulty and cost of making each fixed pile are also reduced.
  • the installation process of a single fixed pile that needs to be fixed on the seabed will be very cumbersome.
  • this embodiment uses at least four fixed piles connected to each other to form a natural piling platform. There is no need to set up an auxiliary piling platform, which greatly reduces the installation cost of fixed piles. Therefore, the sum of the manufacturing cost and installation cost of four fixed piles with a diameter of 1.3 m is far less than the manufacturing cost and installation cost of a fixed pile with a diameter of 6 m.
  • each fixed pile in this embodiment has a diameter of 3m, it can carry a horizontal-axis hydro-generator with an installed power of up to 20MW, breaking the existing upper limit of the installed power of a single machine, and truly increasing the installed power of a single machine.
  • the existing tidal current power generation device has a maximum single-unit installed power of only 2MW. To achieve a power generation of 20MW, up to ten horizontal-axis hydro-generators need to be operated, and at least ten assembly platforms are required for installation.
  • the large-scale tidal current power generation device of the first embodiment of the present invention only needs to install a horizontal-axis hydroelectric generator and an assembly platform to achieve a power generation of 20MW, which greatly reduces the cost and makes the tidal current power generation device more efficient. Commercial use is truly possible.
  • the cost of tidal current power generation device is basically composed of two parts, one is the manufacturing cost and installation cost of the generator, and the other is the manufacturing cost and installation cost of the assembly platform.
  • the manufacturing cost and installation cost of a 2.5MW horizontal-axis turbine generator is 20 million
  • the manufacturing cost and installation cost of two 2.5MW horizontal-axis turbine generators are 40 million
  • a 5MW The manufacturing cost and installation cost of the horizontal axis turbine generator is only 26 million.
  • the assembly platform of the large-scale tidal current power generation device of this embodiment has 8 fixed piles, and two force blocking members 12 are respectively arranged on the two fixed piles 11 on the left and the middle as shown in FIG.
  • the root fixed pile 11 is located on the side of the fixed pile 11 facing the horizontal axis hydroelectric generator 2. If the tidal current power generation device has only four fixed piles, the force blocking member can be installed on the bracket connecting the two fixed piles. In other words, the force blocking member 12 can be directly or indirectly installed on the fixed pile 11.
  • one ends of the at least two force-receiving support members 13 are respectively installed on the left and right sides of the horizontal-axis water turbine generator 2 along the water flow direction D, and the other end respectively abuts against the corresponding force-receiving blocking member 12.
  • one end of the force support 13 refers to the right end
  • the other end of the force support 13 is the left end
  • one end of the force support 13 refers to the left end
  • the other end of the force support 13 is the right end.
  • the force supporting member 13 and the force blocking member 12 of this embodiment are combined to resist the impact force of the water flow on the horizontal axis hydroelectric generator 2.
  • the water flows from bottom to top along the water flow direction D toward the horizontal axis hydroelectric generator 2, because one end of the two force-bearing supports 13 is fixed on the horizontal axis hydroelectric generator 2 respectively.
  • the thrust of the horizontal-axis hydraulic generator 2 can be directly transmitted and decomposed by the water flow.
  • the thrust is successively distributed to each fixed pile 11 through the force supporting member 13, the force blocking member 12 and the bracket 14 in a balanced manner, and all the fixed piles 11 bear the force together.
  • the force-bearing stopper 12 is fixed to the bracket 14 or the fixed pile 11, so the force-bearing stopper 12 will
  • the force support 13 generates a "blocking force" from top to bottom as seen in the direction of Figure 1, and the effects produced by the different forces are offset, so as to achieve a balance, thereby ensuring the horizontal axis turbine generator 2 in the water. It is stable, thereby increasing the upper limit of the horizontal axis water turbine generator 2 that can withstand the thrust of the water flow.
  • the horizontal axis hydroelectric generator is fixed to the seabed by a single bearing pile, and the single load bearing pile will bear all the impact force of the water flow on the horizontal axis hydroelectric generator.
  • the bending moment and shear force generated in this process will be very large.
  • an upper limit is set for the single-unit installed capacity of the horizontal-axis hydro-generator.
  • at least two stress points are provided on the "waist" of the entire power generating device, which effectively disperses the impact force of the water flow on the horizontal axis hydroelectric generator laterally.
  • the tidal current energy generating device uses the kinetic energy of the water flow to generate electricity, the greater the thrust of the water current, the greater the power generation. Therefore, the tidal current energy generating device of this embodiment can carry a higher-power horizontal axis hydroelectric generator.
  • the cross section of the force blocking member 12 is concave.
  • the present invention does not impose any limitation on this.
  • the cross section of the force blocking member 12 may be convex or tapered.
  • the present invention does not make any restrictions on the specific shapes of the force blocking member 12 and the force supporting member 13, and the force blocking member 12 only needs to form an engaging relationship with one end of the force supporting member 13.
  • FIG. 3 briefly illustrates some possible cross-sectional shapes of the force blocking member 12 and the force support member 13.
  • the actual shapes of the force blocking member 12 and the force support member 13 of the present invention are not limited to this.
  • the force-receiving support 13 preferably has an arc or other streamlined appearance. With this arrangement, the resistance of the force-bearing support 13 in the water is reduced as much as possible.
  • the force blocking member 12 and the force supporting member 13 of this embodiment can be fixed by jacks or fixing bolts.
  • the present invention does not impose any limitation on this.
  • the other end of the force blocking member 12 and the force support member 13 can achieve an interference fit. Specifically, when the force support 13 is installed on the force stop 12, the force support 13 and the force stop 12 can be completely clamped without additional jacks or fixing bolts, and the two are fixed. There will be no loosening. During installation, there is no need for installation personnel to enter underwater to perform installation operations, and therefore no additional manholes are required.
  • the manufacturing precision of the force blocking member 12 and the force support member 13 is required to be high, and the cross section of the force support member 13 can be set to a specific shape so as to be firmly engaged with the force blocking member 12 (for example, as shown in the figure). 3 The shape shown on the far right).
  • the impact force of the water flow is very huge.
  • the advantage is that during the installation process, the connection between the stressed support member and the stressed blocking member only needs to rely on the engagement relationship, and no additional fixing and adjustment are required.
  • a jack can also be installed under the force support member.
  • the horizontal axis turbine generator needs to be hoisted from the water from top to bottom, only The jack needs to be raised and the force-bearing support member is lifted up to release the engagement relationship between the force-bearing support member and the force-bearing blocking member, so that the horizontal-axis water turbine generator can be hoisted out of the water.
  • the number of the force blocking member 12 and the force support member 13 are both two.
  • the present invention does not impose any limitation on this.
  • the number of force blocking members and force supporting members may both be four, and the horizontal axis hydro-generator may have two force blocking members and force supporting members on the left and right sides along the water flow direction.
  • the number of the force-bearing support 13 may be two, the number of the force-bearing blocking member 12 may be four, and every two force-bearing members 12 is a set of other force-bearing members 12 fixed on the force support. On one end.
  • the length direction of the force support 13 is perpendicular to the water flow direction D and parallel to the horizontal plane P.
  • the length direction of the force support member may be perpendicular to the water flow direction, but may not be parallel to the horizontal plane, that is, the force support member may be inclined. The more inclined the force-bearing support 13 is, the longer the length of the force-bearing support 13 will be, the greater the amount of steel used, and the greater the bending moment generated. Therefore, the joint end of the force supporting member 13 and the force blocking member 12 needs to be set below the water surface.
  • one end of the two force-receiving supports 13 is directly installed on the generator part of the horizontal-axis hydroelectric generator 2 and is located on the left and right sides.
  • the horizontal-axis hydraulic generator may have a suspension support column, and one end of the two force-bearing supports 13 may be installed on the suspension support column and still be located on both sides of the horizontal-axis hydraulic generator 2.
  • one end of the force supporting member is directly or indirectly installed on the horizontal-axis hydro-generator 2 so as to decompose the force received by the horizontal-axis hydro-generator 2 toward both sides.
  • the positions of the two force-receiving supports 13 fixed on both sides of the horizontal-axis hydro-generator 2 are as close as possible to the horizontal-axis hydro-generator. Bending moment caused by the suspension support column.
  • the horizontal axis hydraulic generator 2 and the force supporting member 13 are welded and fixed on the shore, and assembled to form an inner module.
  • the prototype of the fixed pile 11, the bracket 14 and the force blocking member 12 are also welded and fixedly connected to each other on the shore, and then transported to the installation water area, and at least four fixed piles 11 are separately driven (including but not limited to on the seabed). Drilling, piling and embedding in the base rock layer, pouring concrete into the pile to form a reinforced concrete cast-in-place pile), and then completing the installation of the assembly platform 1.
  • the inner module is hoisted into the installation space 15 of the assembly platform 1 from top to bottom from the water surface, and then the fixing of the force support 13 and the force stop 12 is completed, that is, the installation of the entire tidal energy generating device is completed.
  • all the manufacturing and installation actions of the tidal current power generation device and its assembly platform can be completed above the water surface, eliminating underwater operations, reducing the difficulty of construction, improving the safety of construction personnel, and also greatly Reduce construction and installation costs.
  • the piling method disclosed in another Chinese patent (publication number CN105401564) invented by the present inventor can be used for piling, or other existing piling methods can be used. It will not be described here.
  • the present invention does not impose any limitation on this. It should be noted that in this embodiment, only the piling method of the fixed pile can be consistent with the piling method disclosed in CN10540156, but the structure and installation method of the entire tidal energy generating device are essentially different from the structure and installation method disclosed in CN10540156.
  • the horizontal axis turbine generator in CN10540156 invented by the present inventor is first installed in the inner frame, and then the inner frame is inserted into the outer frame.
  • the arrangement of the inner frame and the outer frame will result in a significant increase in the amount of steel used and a substantial increase in cost.
  • the inventor found that the thrust generated by the water flow is huge and unimaginable, and the maximum thrust can be as high as 2000-3000 tons. Therefore, only by increasing the weight of the inner frame and relying on the friction caused by its own gravity to offset the thrust of the water flow on the hydroelectric generator, this will lead to a sharp increase in the amount of steel used and the cost.
  • This embodiment completely abandons the use of the frame.
  • the entire assembly platform, except for the reinforcement cage used in the process of pouring concrete to form the fixed pile, and the steel for the force support, the force stop, and the bracket, are completely free of other parts. Need steel.
  • the steel consumption of the entire assembly platform is reduced geometrically, and the manufacturing cost is greatly reduced.
  • the turbine generator will withstand the thrust of 23 tons of water flow.
  • the inner frame needs more than 230 tons to ensure the safe operation of the turbine generator.
  • the weight of the entire assembly platform of the tidal current power generation device of this embodiment only needs to be 125 tons (if the buoyancy generated by the hollow force support and the hollow generator nacelle is removed, there is actually only 25 tons of gravity in the water.
  • a single-unit horizontal-axis hydro-generator with an installed capacity of 1.5MW can be operated smoothly.
  • the impeller diameter is 15m and the cross-section of the impeller is 177m 2.
  • the hydro-generator can withstand the thrust of 177 tons of water flow. If the installation method and structure previously invented by the inventors are adopted, a frame of up to 1,800 tons is required to carry a 1.5MW horizontal axis turbine, and a frame of this weight is impossible to achieve from a technical or cost perspective. Therefore, the problem of frame alone restricts the existing single-unit scale of horizontal-axis turbine generators.
  • the horizontal axis turbine generator in CN10540156 is rotatably fixed on the uppermost and lowermost part of the inner frame through a central rotating shaft.
  • the horizontal-axis turbine generator is prone to vibration during operation.
  • the shaft turbine generator will be very easy to damage, which makes it impossible to break through the single-unit scale of the horizontal shaft turbine generator.
  • the tidal current power generation device provided by this embodiment is provided with at least two "binding points" at the waist or near the waist of the horizontal-axis hydraulic generator, and the horizontal-axis hydraulic generator is directly and firmly fixed to the supporting member. , And then the force-bearing support member is also firmly fixed to the force-bearing blocking member, and the force-bearing member and the bracket are also firmly fixed in relation to the fixed pile.
  • the horizontal axis turbine generator and the assembly platform are firmly fixed, and no components will vibrate beyond the safe range in the water, avoiding the problem of resonance. Therefore, the tidal current power generation device provided in this embodiment can smoothly run a horizontal-axis hydro-generator with a larger installed scale.
  • the assembly platform 1 has at least two guide grooves 121, which are respectively located on the left and right sides of the horizontal axis turbine generator 2 along the water flow direction D.
  • the guide grooves 121 lead from above the water surface to below the water surface, at least two The force blocking members 12 are respectively fixed to the bottom ends of the corresponding guide grooves 121.
  • the guide groove 121 may be provided on the corresponding fixed pile 11 or the bracket 14 and located on the side of the fixed pile 11 or the bracket 14 facing the horizontal axis hydroelectric generator 2.
  • One end of the guide groove 121 is located above the water surface P, and the other end may be located at the same level as the center point of the horizontal axis hydroelectric generator 2 or a position lower than the center point.
  • the function of the guide groove 121 is to facilitate the installation or fixation of the force-bearing support 13.
  • one end of the force support 13 can slide from the water along the guide groove 121 to the water, and then be fixed with the force blocking member 12 at the bottom end of the guide groove 121.
  • the assembly platform 1 also includes at least two sets of fence guide grooves 16 for installing or fixing fences.
  • the direction of water flow is shown as D in Fig. 1, the lower part of Fig. 1 is upstream, and the upper part of Fig. 1 is downstream), and each group of fence guide grooves 16 pass from above the water surface to below the water surface.
  • each group of fence guide grooves 16 includes two fence guide grooves.
  • another set of fence guide grooves 16 are located on the downstream side of the two downstream fixed piles 11 (the two uppermost fixed piles) in FIG. 1.
  • the left and right sides of the fence can be inserted into the fence guide groove 16 from top to bottom along a set of fence guide grooves 16, and then slide to the bottom end by its own gravity, thereby completing the installation and fixing of the fence. .
  • the installation of the fence guide groove 16 makes the installation of the fence easier, and the installation of the fence is not required to be installed in the sea, and the installation of the fence can be completed by directly operating on the sea.
  • the fence can be pulled out along the fence guide groove 16 from bottom to top, and the personnel only need to operate on the water surface. Therefore, the arrangement of the fence guide groove 16 also facilitates the cleaning and replacement of the fence.
  • the cost of fence installation and maintenance and replacement is reduced. This embodiment does not impose any limitation on the specific type of the fence.
  • the assembly platform 1 includes at least one man-passing pipe 17 that passes from above the water surface to below the water surface, so that people can pass through the man-passing pipe 17 to below the water surface for maintenance or fixing operations.
  • One end of the human passage 17 is located above the water surface P, and the other end is located below the water surface P to communicate with the horizontal axis hydraulic generator 2 or the force support 13 or the force blocking member 12.
  • the number of human passages 17 is two, and the two human passages 17 are arranged along the bracket 14 respectively.
  • the human-passing pipe 17 can be connected to the force-bearing support 13 respectively, and personnel can reach the force-bearing support 13 through the human-passing pipe 17 to fix the force-bearing support 13 and the force blocking member 12 Install.
  • the human-passing pipe 17 may be arranged in a fixed pile 11 on both sides of the horizontal-axis hydro-generator 2 and communicate with the force supporting member 13 or the force blocking member 12 respectively.
  • the human passage 17 can also be arranged in the bracket 14.
  • the two force-bearing supports 13 may have a hollow structure, and personnel can reach the interior of the horizontal-axis water turbine generator 2 through the passage 17 and the force-bearing support member 13. Internal maintenance operations (such as oil update, gear replacement, seal replacement, etc.).
  • the assembly platform may only have one passage for people, and the passage for people is also set in the fixed piles. People can reach the supporting member on one side through the passage for people. It can be fixedly installed with the force-bearing block, and it can also reach the inside of the horizontal-axis turbine generator through the force-bearing support.
  • the assembly platform may only have one passage for people, the passage for people can be arranged in the fixed pile and can be connected to the force blocking member, and the installer can reach the inside of the force blocking member through the passage pipe.
  • a fixed installation is carried out between the force supporting part and the force blocking part.
  • the assembly platform can be provided with a special passage for people to directly communicate with the interior of the horizontal-axis turbine generator from above the water surface.
  • the assembly platform 1 further includes at least one blower 181 and a ventilation pipe 182.
  • the ventilation pipe 182 can be fixedly or detachably arranged along the inside of the passage 17 or outside the passage 17.
  • the vent pipe 182 From above the water surface P to below the water surface P so that the work area under the water can be exchanged.
  • the existing tidal current power generation device has not considered the situation of underwater installation or maintenance.
  • the inventor previously considered underwater maintenance, but ignored the problems of toxic and harmful gases and excessive carbon dioxide concentration caused by the high temperature generated by the internal machine running for a long time. If underwater operations are required, personnel need to stay underwater for a long time, which is prone to hypoxia or carbon dioxide poisoning.
  • the blower 181 and the ventilation pipe 182 in this embodiment constitute a fresh air system, which greatly guarantees the life safety of maintenance personnel or installation personnel entering the water.
  • the blower can be started to change the air in the work area below the water surface.
  • the fresh air system may have a more complex structure, such as an independent air supply system and an exhaust system, etc., which will not be described here.
  • the assembly platform 1 further includes at least one pump 183 and at least one drain pipe 184.
  • the drain pipe 184 can be fixedly or detachably arranged along the inside or outside the passage 17,
  • the drain pipe 184 passes from above the water surface P to below the water surface P, and the pump 183 extracts the accumulated water in the working area below the water surface and discharges it above the water surface through the drain pipe 184. Since most of the entire tidal current power generation device is located in the water, after a long period of operation, the sealing ring is prone to loosening, and it is difficult to guarantee that there will be no water leakage at the sealing ring.
  • the pump 183 and the drain pipe 184 By setting the pump 183 and the drain pipe 184, the life safety of personnel is greatly guaranteed.
  • the pump 183 when a person needs to perform underwater work, start the pump 183 to run for a period of time first, and observe whether there is accumulated water discharged from the drain pipe 184. Personnel may not enter the passage 17 until the drainage pipe 184 has no obvious water discharge.
  • the pump 183 keeps working until the personnel finish the work and return to the surface above the water.
  • the present invention does not impose any limitation on the working form of the sump pump.
  • the water pump 183 can be operated regularly to extract the accumulated water inside and discharge it above the water surface through the drain pipe 184, so as to prevent the accumulated water from damaging the components and ensure the life safety of workers.
  • the ventilation pipe 182, the drainage pipe 184, and the passage pipe 17 may all be arranged along the bracket 14 or the fixed pile 11, and these pipes may all communicate with the inside of the force supporting member 13.
  • the ventilation pipe 182 and the drainage pipe 184 may be arranged along the hollow force-bearing support 13 to reach the interior of the horizontal-axis hydroelectric generator 2.
  • a special ventilation pipe 182, a drainage pipe 184, and a human-passing pipe 17 may be provided in the fixed pile 11 to pass from the water to the water.
  • the assembly platform 1 may further include at least two fixed component boxes 18, each fixed component box 18 is arranged corresponding to the force blocking member 12, the fixed component box 18 is a hollow structure, and personnel can enter the fixed component The inside of the box 18 works.
  • the fixed component box 18 can be installed on an end of the force supporting member 13 that abuts against the force blocking member 12 for fixedly connecting the force blocking member 12 and the force supporting member 13.
  • each fixed component box 18 communicates with a human passage 17.
  • the human passage 17 in this embodiment directly leads to the inside of the fixed component box 18 instead of directly connecting with the force-bearing support 13.
  • each fixing component box 18 has a sealing device 185 and a fixing component 186.
  • the fixing component 186 includes at least one fixing bolt or at least one jack.
  • the sealing device 185 is correspondingly provided at the fixing component 186.
  • the installer can enter the fixed assembly box 18 through the passage 17 and start to adjust the fixed assembly 186 (such as tightening the fixing bolts or jacking up the jack), so that the fixed assembly 186 is The top end firmly abuts on the inner wall of the positioning groove of the force blocking member 12.
  • the fixed component box 18 is stuck in the force-bearing blocking member 12 to avoid the shaking of the horizontal-axis hydraulic generator 2.
  • the horizontal-axis water turbine generator 2 is firmly positioned, and no vibration phenomenon beyond the acceptable range will be generated.
  • the blower 181 has been working, and fresh air is fed in from the ventilation pipe 182.
  • the water pump 183 can also work all the time to discharge possible accumulated water from the drain pipe 184, thereby ensuring the life safety of personnel.
  • the human passage 17 can also directly lead to the inside of the force support 13 or the force stop 12, thereby completing the force support 13 and the force stop 12 Fixed connection.
  • a side plate 19 is provided on the side of each row of fixed piles 11 facing the horizontal axis hydroelectric generator 2.
  • the side plate 19 can form a water channel to play a rectifying effect, that is, it can gather the water flow to better guide the horizontal axis hydroelectric generator 2 so as to improve the power generation efficiency.
  • side plates may be provided on the upper, lower, left, and right sides, so as to form a water channel to guide the water to the horizontal axis hydroelectric generator 2 in a concentrated manner.
  • each fixed pile 11 of the assembly platform 1 is provided with a concrete protection device 111 in the area above the lowest tide line L to protect each fixed pile 11 from being affected by the tide.
  • the strong corrosion of the belt greatly prolongs the service life of the fixed pile 11, thus prolongs the service life of the assembly platform 1, and reduces the maintenance frequency and cost. Since water plays the role of isolating oxygen in the air, the part of the fixed pile 11 under water is not easy to corrode, and the part of the fixed pile 11 above the water surface is the most likely to rot.
  • the concrete protection device 111 If the concrete protection device is not provided, once the part of the fixed pile 11 on the water rots, the force transmission between the fixed piles 11 will be unbalanced, and the entire assembly platform 1 may be unbalanced or even collapsed.
  • the service life of the entire assembly platform 1 can be as long as 50 years. With the rising and falling tides, the height of the water surface P will change, so the lowermost end of the concrete protection device 111 is preferably set at the lowest tide line L. In practical applications, the lowermost end of the concrete protection device 111 can be lower than the lowest tide line L.
  • a protective cover is provided in the area of the fixed pile 11 above the lowest tide line L, and then concrete is poured into the protective cover to form a concrete protection device 111.
  • Fig. 5 shows a partial top view of a large tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 6 shows a partial side view of a large tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 7 shows a top view of a single inner module of a large tidal current power generation device according to a second embodiment of the present invention.
  • Fig. 8 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a second embodiment of the present invention. Please refer to Figure 5 to Figure 8 together.
  • the structure and function of the fixed component box 18, the blower 181, the ventilation pipe 182, the water pump 183, the drain pipe 184, and the side plate 19 are basically the same as those of the corresponding components in the first embodiment, so the same reference numerals are used. Only the differences are explained below.
  • the large-scale tidal current power generation device includes an assembly platform 1, at least one horizontal-axis hydroelectric generator 2 and at least one suspension support column 31. At least one horizontal axis turbine generator 2 is detachably installed in the assembly platform 1.
  • Figure 5 only depicts one module on the most side of the large tidal current power generation device, so only one assembly platform 1 and one horizontal axis hydro-generator 2 are shown. In practical applications, multiple assembly platforms 1 and multiple horizontal axis hydraulic generators 2 can be arranged in an array, thereby increasing the power generation of the entire power generation device.
  • FIG. 5 Another horizontal-axis turbine generator 2 will be installed on the right side of the tidal current power generation device shown in Figures 5 and 6, so there is an additional force blocking member 12 located in the middle of the right side.
  • the fixed pile 11 or the bracket 14 on the right side will additionally have a guide groove 121.
  • the tidal current power generation device further includes at least one suspension support column 31.
  • One end of the suspension support column 31 is located on the water surface P, and the other end is connected to the horizontal axis hydroelectric generator 2 or the force blocking member 12 or is supported by the force.
  • the piece 13 enables people to reach below the water surface P through the suspension support column 31 to perform maintenance or fixing operations.
  • the assembly platform of this embodiment also includes at least two fixed component boxes 18, and each fixed component box 18 is arranged corresponding to the force blocking member 12 and is hollow.
  • the tidal current power generation device in this embodiment includes three suspension support columns 31.
  • the suspension support column 31 located in the middle is located on the water surface P, and the other end is connected to the horizontal axis hydroelectric generator 2.
  • the other two suspension support columns 31 are respectively located on both sides of the horizontal axis hydroelectric generator 2 along the water flow direction D, and the other ends of the two suspension support posts 31 are respectively connected to the fixed components located on both sides of the horizontal axis hydroelectric generator 2 Box 18.
  • the suspension support columns 31 on both sides can be fixed in the guide groove 121.
  • the guide groove 121 not only guides the sliding of the fixed component box 18, but also facilitates the installation and fixation of the fixed component box 18.
  • the guide groove 121 also functions to fix and guide the suspension support column 31.
  • the other ends of the suspension support columns 31 on both sides can directly communicate with the force-bearing support 13.
  • a climbing ladder can be provided inside the suspension support column 31.
  • Personnel can enter the interior of the horizontal-axis hydro-generator 2 through the ladder inside the suspension support column 31 in the middle to perform work (such as maintenance work such as replacement of sealing rings, replacement of engine oil, or arrangement of pipelines).
  • work such as maintenance work such as replacement of sealing rings, replacement of engine oil, or arrangement of pipelines.
  • the horizontal-axis hydraulic generator 2 fails, there is no need to lift the horizontal-axis hydraulic generator 2 out of the water, and personnel can directly enter the interior of the horizontal-axis hydraulic generator 2 for maintenance.
  • Personnel can also reach the fixed component box 18 through the suspension support columns 31 on both sides to complete the installation and fixation work between the fixed component box 18 and the force blocking member 12.
  • the bearing pile and the horizontal-axis turbine generator must be fixed firmly, which also means that it is very difficult to release the connection between the two, not to mention the Operation under water makes maintenance very difficult. Therefore, many existing tidal current power generation devices are not repaired at all. Once the horizontal-axis turbine generator is damaged (for example, the sealing ring becomes loose due to long-term use, which causes water to enter the horizontal-axis turbine generator or the horizontal-axis turbine generates electricity. The engine oil needs to be replaced, etc.), then the entire power generation device is directly scrapped. This is also one of the important reasons for the short service life and high cost of the existing tidal current power generation device, which makes the tidal current power generation device unable to be commercialized.
  • the horizontal-axis hydraulic generator 2 in this embodiment when maintenance is required, the maintenance personnel can directly enter the interior of the horizontal-axis hydraulic generator 2 through the suspension support column 31 to directly perform underwater maintenance.
  • the service life of the assembly platform of this embodiment can be as long as 50 years, but the upper limit of the use of the horizontal-axis turbine generator is 20 years.
  • the horizontal-axis turbine generator 2 reaches the end of its service life, only Remove the fixed connection between the horizontal axis turbine generator 2 and the assembly platform 1, then the horizontal axis turbine generator 2 can be hoisted out of the water from the bottom to the top, and the new horizontal axis turbine generator 2 can be replaced. Install.
  • the horizontal axis water turbine generator 2 of this embodiment adopts an upside-down detachable installation method.
  • the maintenance and replacement cost and difficulty of the horizontal axis water turbine generator 2 are far lower than the maintenance of the horizontal axis water turbine generator directly fixed on the seabed. Cost and difficulty.
  • the horizontal-axis hydraulic generator 2 of this embodiment is fixed underwater by the suspended support column 31 and the force-bearing supports 13 on both sides to ensure that the horizontal-axis hydraulic generator 2 will not shake under the huge thrust of the water flow. , The vibration generated is also within the safety range. Therefore, the tidal current power generation device provided in this embodiment can run a larger-scale horizontal-axis hydro-generator, which also means that the single-unit installed power of the horizontal-axis hydro-generator will be greater. The existing tidal current power generation device can withstand a maximum single-unit installed power of 2MW.
  • the tidal current power generation device of this embodiment can directly carry and run horizontal-axis hydroelectric generators with a single-unit installed power of 5MW or even 10MW or 20MW. This has greatly promoted the development of the ocean energy power generation industry and promoted technological progress, bringing fundamental changes to the industry.
  • the existing tidal current power generation device uses a single-unit installed power of 2MW, it cannot continue to generate electricity because it has not solved maintenance and other problems. Even though some tidal current power generation devices are considered for maintenance, the high maintenance cost makes the cost of power generation of tidal current power generation much higher than the cost of power generation from other energy sources. Therefore, the commercial value of existing tidal current power generation devices has always been small.
  • the suspension support column of this embodiment not only plays a supporting role, but also allows people to enter the interior of the horizontal-axis turbine generator for maintenance, which greatly reduces the maintenance cost.
  • the large-scale tidal current power generation device further includes at least one connector 4 that connects the end of the suspension support column 31 above the water surface and the assembly platform 1 horizontally or longitudinally.
  • the connecting piece 4 When the connecting piece is connected laterally, the connecting piece 4 also fixedly connects the ends of the three suspension support columns 31 above the water surface.
  • the connection relationship between the connecting piece 4 and the assembly platform 1 can be released.
  • the airtight hollow suspension support column 31 functions as a passage 17 for people.
  • three suspension support columns 31, two fixed component boxes 18, two force-bearing supports 13 and horizontal-axis hydro-generator 2 together constitute an inner module.
  • the present invention does not impose any limitation on this.
  • the human-passing pipes 17 on both sides can be directly arranged in the fixed pile 11, although in this case, if maintenance is required, the fixed pile of the assembly platform may face the risk of being scrapped, which is less economical. .
  • each suspension support column 31 (that is, the human-passing pipe 17) in the large-scale tidal current power generation device of this embodiment is correspondingly provided with a blower 181, a ventilation pipe 182, a water pump 183, and a drain pipe 184.
  • a blower 181, a ventilation pipe 182, a water pump 183, and a drain pipe 184 To protect the life safety of underwater workers.
  • the structure and function of the blower 181, the ventilation pipe 182, the water pump 183, and the drain pipe 184 are the same as those of the first embodiment, and will not be repeated here.
  • the number of the suspension support column 31 may be one, the suspension support column 31 located in the middle is a closed hollow structure, and the suspension support columns 31 located on both sides may not be hollow or do not require both sides.
  • the force support 13 and the force blocking member 12 are fixed or the fixing component box 18 and the force blocking member 12 are fixed. As shown in FIG.
  • the number of suspension support columns 31 may be two, the suspension support columns 31 located on both sides are a closed hollow structure, and the suspension support column 31 located in the middle may not be hollow or need not be in the middle. Personnel can reach the interior of the horizontal-axis hydro-generator 2 through the suspension support column 31 and the hollow force-bearing support 13 on either side. As shown in FIG.
  • the number of the suspension support column 31 may be one and located on the left or right side, and the suspension support column 31 in the middle and the suspension support column 31 on the other side may not be hollow or need not
  • personnel enter the force support 13 through the leftmost suspension support column 31, and then pass through the hollow force support 13 to reach the inside of the horizontal-axis hydro-generator 2. And it can pass through the horizontal-axis hydro-generator 2 and another force-bearing support 13 to the rightmost end.
  • the present invention does not impose any limitation on this.
  • the force-bearing support 13 may not be hollow, and there is no need for people to pass through the inside, and personnel can respectively pass through the three hollow suspension support columns 31 to reach the corresponding location.
  • the blower 181, the ventilation pipe 182, the water pump 183, and the drain pipe 184 can all be arranged correspondingly.
  • Fig. 12 shows a top view of a large-scale tidal current power generation device according to a sixth embodiment of the present invention.
  • the upper dashed circle is an enlarged view of the lower dashed circle mark.
  • the structure and function of the blower (not shown), ventilation pipe 182, water pump (not shown), drain pipe 184, side plate 19, etc. are basically the same as those of the corresponding components in the first embodiment, so the same reference numerals are used. Only the differences are explained below.
  • the assembly platform 1 does not include the fixed component box in the first embodiment, but still has a sealing device and a fixed component (such as a fixing bolt or a jack).
  • a sealing device such as a fixing bolt or a jack
  • One end of the force supporting member 13 is directly installed and fixed on the force blocking member 12 through a fixing component, and the sealing device seals the connection.
  • the four people-passing pipes 17 are arranged along the outside of the fixed pile 11, one end of the human-passing pipe 17 is above the water surface, and the other end is connected to the force blocking member 12.
  • a person can enter the force blocking member 12 through the passage 17, and then adjust the fixing assembly, so as to fix the force supporting member 13 and the force blocking member 12.
  • this human-passing pipe 17 is set on the support 14, and the underwater working area can be reached through this one-passing pipe.
  • the fixed components in each place are used for fixed operation, and this setting method has the lowest cost.
  • the blower, the ventilation pipe 182, the water pump, and the drain pipe 184 can all be arranged correspondingly to ensure the safety of personnel.
  • Fig. 13 shows a top view of a large tidal current power generation device according to a seventh embodiment of the present invention.
  • the assembly platform of the seventh embodiment, the horizontal axis turbine generator 2, the fixed pile 11, the concrete protection device 111, the force blocking member 12, the force support member 13, the bracket 14, the installation space 15, the fence guide groove 16 The structure and function of the corresponding elements in the first embodiment are basically the same as those of the corresponding components in the first embodiment, so the same reference numerals are used. Only the differences are explained below.
  • the tidal current power generation device does not include a fixed component box.
  • the assembly platform also includes two sets of shock-absorbing devices 21, and each set of shock-absorbing devices 21 is arranged between the force supporting member 13 and the force blocking member 12.
  • Each group of shock-absorbing devices 21 includes two shock-absorbing parts, which are respectively fixed on the two sides of the upstream and downstream sides at one end of the force-bearing support 13 away from the horizontal-axis hydro-generator 2.
  • Each shock absorber abuts against the force blocking member 12.
  • the shock absorber 21 can be made of a special polyethylene polymer material, rubber material or spring.
  • FIG. 14 is a schematic diagram of a fence provided according to the eighth embodiment of the present invention.
  • the dotted circle on the right in FIG. 14 is a top view of the mark by the dotted circle on the left.
  • the assembly platform includes at least two fences 3, which are respectively arranged on the upstream and downstream sides of the horizontal-axis turbine generator 2, and the width W of each fence 3 along the water flow direction is greater than or equal to 8 cm.
  • Existing tidal current power generation devices often ignore the damage to the impeller of the hydroelectric generator caused by foreign objects in the ocean (such as marine garbage, floating ice in the sea, etc.). The inventor has noticed this point, and therefore adopts the method of setting a fence to reduce the probability of foreign matter from the ocean being caught in the impeller.
  • the height of each fence grid along the depth direction is still the diameter of the steel wire, that is, about 8 mm.
  • the width W of the fence 3 along the direction of the water flow can be 30 cm, which can effectively prevent the impact of ice in the waters near northern Canada and at the same time ensure that the steel wire will not be stranded.
  • the length of the fence perpendicular to the water flow direction and parallel to the horizontal plane direction is determined according to the size of the assembly platform corresponding to the installation, which is not limited by this patent, for example, it can be 15m*20m.
  • the height of the fence along the depth of the water is determined according to the stress conditions of the water flow environment of the implementation site, and this patent does not make specific limitations.
  • the mesh of the fence can be a square or rhombus structure. This patent does not limit the size of the mesh distance, and the mesh can be 30cm*30cm. In addition, this patent does not limit the specific materials of the fence bracket and the barrier.
  • Fig. 15 is a schematic diagram of a large-scale tidal current power generation device according to a ninth embodiment of the present invention.
  • Fig. 16 is a schematic diagram of the installation of a large-scale tidal current power generation device according to a ninth embodiment of the present invention.
  • a large-scale tidal current power generation device includes at least two assembly platforms 1 and at least three horizontal axis hydroelectric generators 2.
  • the assembly platform 1 and the horizontal-axis hydraulic generator 2 in the ninth embodiment may have the same structure as the assembly platform and the horizontal-axis hydraulic generator disclosed in the second embodiment, and the same structures are represented by the same reference numerals. .
  • the tidal current power generation device in the ninth embodiment also has all the other components mentioned in the first or second embodiment, which will not be repeated here.
  • the large-scale tidal energy generating device includes at least four fixed piles 11, at least four fixed piles 11 are connected by brackets 14 to form an installation space 15, and one end of each fixed pile 11 is fixed to the sea by piling.
  • the other end of the bed F extends above the water surface.
  • At least four fixed piles 11 are arranged in two rows along the water flow direction, and at least two fixed piles 11 in each row are arranged in order along the water flow direction.
  • At least one horizontal axis hydraulic generator 2 is installed in the installation space 15 of each assembly platform 1.
  • At least two assembly platforms 1 are placed left and right along the direction of water flow, and the interval G between the two assembly platforms 1 matches the diameter of the impeller of a horizontal-axis turbine generator 2 so that at least one additional horizontal-axis turbine
  • the generator 2 can be installed between the two assembly platforms 1.
  • the direction of the gap G is parallel to the horizontal plane and perpendicular to the direction of water flow.
  • the length of the gap G is greater than the diameter of the impeller of a horizontal-axis hydraulic generator 2 so that a horizontal-axis hydraulic generator 2 can be installed between the two assembly platforms 1.
  • Each assembly platform 1 is equipped with a horizontal axis hydroelectric generator 2 along the direction parallel to the horizontal plane, and one or more horizontal axis hydroelectric generators 2 can be installed along the water depth direction (that is, the direction perpendicular to the horizontal plane).
  • a horizontal axis water turbine generator 2 is installed between the two assembly platforms along the direction parallel to the horizontal plane, and one or more horizontal axis water wheels can be installed along the water depth direction (that is, the direction perpendicular to the horizontal plane).
  • the tidal current power generation device used in the patents previously applied by the inventor and specific implementation cases first installs a horizontal-axis hydraulic generator on an inner frame to form an inner module, and then the outer frame is piled and fixed on the seabed to form an inner module. Assemble the platform, and then hoist the inner module into the outer frame located in the water to complete the installation of the tidal current power generation device.
  • the total manufacturing cost of the tidal current power generation device includes the manufacturing cost of the assembly platform, the manufacturing cost of the outer frame and the inner frame, and the manufacturing cost of the horizontal-axis turbine generator itself.
  • the tidal current power generation device of this embodiment and any of the aforementioned embodiments abandons the use of the traditional frame, greatly reduces the amount of steel required in the manufacturing process, and thereby greatly reduces the manufacturing cost.
  • the installation cost of the existing tidal current power generation device includes the installation cost of the assembly platform and the installation cost of the internal module. If the inner module includes a frame, the installation cost of the inner module will include the installation cost of the generator itself and the installation cost of the corresponding frame. If you want to install three hydro-generators in a direction perpendicular to the direction of water flow and parallel to the horizontal plane, you need the installation cost of three frames plus the installation cost of three hydro-generators plus the cost of three assembly platforms. Installation cost.
  • the installation method of this embodiment directly reduces one platform in addition to no need to install the frame, that is, only two installation platforms are needed to install three hydro-generators, which makes the installation cost of tidal current power generation devices sharp. reduce. If five hydroelectric generators need to be deployed, only three assembly platforms are needed.
  • the cost of the assembly platform and the hydroelectric generator may account for half. In most cases, the cost of the assembly platform may even be higher than the cost of the hydroelectric generator.
  • the installation method disclosed in this embodiment greatly reduces the "stretch" cost of the tidal current power generation device in the direction perpendicular to the water flow and parallel to the horizontal plane, realizes a lower-cost array arrangement, and truly realizes the tidal current power generation device. Large-scale.
  • the existing tidal current power generation device has a low utilization rate of water flow and wastes resources. For example, if the diameter of the fixed pile is 3m, another fixed pile needs to be driven 9m away. Otherwise, the adjacent assembly platform will not be firmly fixed, and during operation, the pile may collapse and skew, and the entire device must be scrapped and reinstalled.
  • the installation method of this embodiment completely avoids this problem in the prior art, and realizes full utilization of tidal energy while reducing costs.
  • Fig. 17 is a schematic diagram of a large-scale tidal current power generation device according to a tenth embodiment of the present invention.
  • at least two horizontal-axis water turbine generators 2 can be installed in each assembly platform 1 along the water depth direction.
  • the present invention does not impose any limitation on this. In practical applications, one can be installed in different installation spaces according to different water depths, and some can be installed with multiple horizontal-axis turbine generators.
  • the fence in the eighth embodiment can be applied to the tidal current power generation device of any of the first, second, third, fourth, fifth, sixth, seventh, ninth, and tenth embodiments.
  • the fence in the eighth embodiment It can also be used in any existing tidal current power generation device.
  • the tidal current power generating device of any one of the first, second, third, fourth, fifth, sixth, seventh, ninth, and tenth embodiments may also adopt fences of other structures.
  • a plurality of tidal current power generating devices disclosed in the first, second, third, fourth, fifth, sixth, seventh, and tenth embodiments can be installed according to the method disclosed in the ninth embodiment.
  • the large tidal current power generation devices disclosed in the first, second, third, fourth, fifth, sixth, seventh, and tenth embodiments can also be arranged in arrays according to other existing arrangements.
  • the installation method of the ninth embodiment can also be applied to existing tidal current power generation devices of other structures.
  • the structure of each assembly platform and inner module in the ninth embodiment may be completely the same as the first, second, third, fourth, fifth, sixth, seventh, and tenth embodiment, or may be different.
  • each assembly platform and inner module of the tidal current power generation device of the tenth embodiment can be completely the same as the first, second, third, fourth, fifth, sixth, and seventh embodiments.
  • the present invention forms an installation space by connecting four fixed piles and brackets together, and then the horizontal-axis turbine generator is fixed in the installation space, instead of installing the horizontal-axis turbine generator as in the prior art
  • the use of steel is greatly reduced, and the manufacturing and installation costs are reduced.
  • the present invention can evenly transmit the thrust of the water flow received by the horizontal-axis turbine generator to both sides by arranging the force-receiving support members and the force-receiving blocking members located on both sides of the horizontal-axis hydraulic turbine generator, thereby dispersing it to the entire
  • the assembly platform enables the entire assembly platform to carry a single horizontal axis hydro-generator with greater power, which greatly reduces the power generation cost of the tidal current power generation device.
  • the horizontal axis hydroelectric generator of the present invention has a "fixed point" in the water, thus avoiding the horizontal axis hydroelectric generator in the prior art under the huge thrust of the water flow, which is easily damaged due to the vibration of the horizontal axis hydroelectric generator. problem.
  • the large-scale tidal current power generation device and its assembly platform provided by this application, the large-scale tidal current power generation device can be truly realized, and the cost of tidal current power generation can be reduced to lower than that of thermal power generation. Commercial promotion and application.

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Abstract

一种大型潮流能发电装置及其总成平台(1),总成平台内安装有至少一台水平轴水轮发电机(2)。其中,总成平台包括至少四根固定桩(11)、至少两个受力阻挡件(12)、至少两个受力支撑件(13)以及支架(14),至少四根固定桩通过支架连成一体且围绕形成一个安装空间(15),至少一个水平轴水轮发电机安装于安装空间内。每根固定桩的一端打桩固定于海床,另一端延伸到水面以上。至少四根固定桩沿着水流方向分左右两列布放,其中每一列固定桩沿着水流方向布放。至少两个受力阻挡件分别固定于对应的固定桩或支架上且位于水面以下水平轴水轮发电机沿水流方向的左右两侧。至少两个受力支撑件的一端分别安装在水平轴水轮发电机沿水流方向的左右两侧,另一端分别抵靠在对应的受力阻挡件上。

Description

大型潮流能发电装置及其总成平台 技术领域
本发明属于潮流能发电领域,尤其涉及一种大型潮流能发电装置及其总成平台。
背景技术
海洋能(包含潮流能、波浪能、温差能、盐差能、海流能等)是一种清洁无污染的可再生能源,其储量丰富,分布广泛,具有极好的开发前景和价值。现今能源日益短缺,温室效应日益严重,能源需要低碳化,所以风能、海洋能等清洁能源是未来能源的发展方向。但现在这些清洁能源的发电设备,除了风能利用比较成熟外,海洋能的利用还是在起步阶段,没有通用和成熟的设备,发电功率相较于其他能源的发电功率较低。最重要的是,现有的海洋能发电装置无论是制造成本、安装成本还是维修成本,都远远高于其他能源发电的成本,这成为了制约海洋能发电装置商业化运用和推广最大的阻碍。
目前利用海上风力进行发电的风力发电装置,单机装机功率最大可以做到5MW。它是将一个塔固定在海底,然后风力发电机固定于塔的顶端且位于海面以上,采集风能进行发电。塔最下端的直径为6.242m,最上端的直径为4.170m,塔径平均为5.206m,整个塔高96m。换言之,为了实现单机装机功率达到5MW,需要设置将近100m高的塔,并且直径最大处要大于6m才能够承载这个功率的发电机。这样的一个塔,重达439吨,造价和安装费用都不菲。因为高昂的成本,无法转换为真正的经济价值。即便想要大规模运用,也因为高昂的成本望而却步。
采用风力发电,整个叶轮的直径哪怕做到230m,也不过12MW的发电量,但是对应的塔高需要做到195m(叶片最下端需要离地30m,叶轮半径为165m)。但是利用潮流能进行发电,叶片直径只需要做到70m,理论上可达到30MW的发电量,并且桩的高度仅需做到40m(叶片离地5m,叶轮半径35m)。因此,相比海上风力发电,潮流能发电大大降低了塔筒高度,减少了成本,利用潮流能发电的发电效率将远高于利用海上风能进行发电。
传统的潮流能发电装置通常采用两种固定方式,一种是漂浮式固定,即通过浮床漂浮在海中并通过钢索固定在海床或者两岸,另一种是海床固定式,即通过一根固定桩直接固定在海底。由于漂浮式固定还是主要利用波浪能进行发电,相比深处的潮流能发电量不高,并且能够悬浮的发电机规模很小,所以经 济性价值较小,于实际应用中逐渐舍弃。第二种海床固定式为现有的潮流能发电装置真正投入实际应用采用的固定方式。
目前,现有的潮流能发电装置真正投入运用的发电模组最大的单机装机功率是2MW。单机装机功率超过2MW的截止目前为止全世界没有成功实施的案例。受到单机发电机组规模的限制,大部分潮流能发电装置成本极高,无法真正投入商业运用,因此也无法产生商业价值。具体而言,传统的潮流能发电装置和海上风力发电装置类似,也是通过一根固定桩直接固定于海底。由于海水冲击力巨大,所以固定桩必须具有足够大的直径才能抵抗弯矩,直径越大的固定桩,其打桩成本越高。特定直径的固定桩,其承受力有上限值,因此也对应地只能承载一定规模以内的水平轴水轮发电机。固定桩无论从成本还是技术角度都无法无限制地做大,因此也造成单个水平轴水轮发电机的装机功率无法突破。
发明内容
本发明为了克服现有技术中的至少一个不足,提供一种大型潮流能发电装置及其总成平台。
于第一方面,本发明提供一种大型潮流能发电装置的总成平台,其内安装有至少一台水平轴水轮发电机。大型潮流能发电装置的总成平台包括至少四根固定桩、至少两个受力阻挡件、至少两个受力支撑件以及支架。至少四根固定桩通过支架连成一体且围绕形成一个安装空间,至少一个水平轴水轮发电机安装于安装空间内,每根固定桩的一端打桩固定于海床,另一端延伸到水面以上,至少四根固定桩沿着水流方向分左右两列布放,其中每一列至少两根固定桩沿着水流方向依次布放。至少两个受力阻挡件分别固定于对应的固定桩或支架上且位于水面以下水平轴水轮发电机沿水流方向的左右两侧。至少两个受力支撑件的一端分别安装在水平轴水轮发电机沿水流方向的左右两侧,另一端分别抵靠在对应的受力阻挡件上,以抵挡水流对水平轴水轮发电机的冲击力。
于本发明的第一方面的一实施例中,总成平台还包括至少两组避震装置,每组避震装置设置于受力支撑件与受力阻挡件之间。
于本发明的第一方面的一实施例中,总成平台具有至少两个导槽,分别设置于对应的固定桩或支架上且位于水平轴水轮发电机沿水流方向的左右两侧,导槽的一端位于水面以上,另一端通向水面以下,至少两个受力阻挡件分别固定于对应的导槽的另一端。
于本发明的第一方面的一实施例中,总成平台还包括至少两组用于安装或固定栅栏的栅栏导槽,至少两组栅栏导槽分别设置在水平轴水轮发电机的上下游两侧,每组栅栏导槽都从水面以上通到水面以下。
于本发明的第一方面的一实施例中,总成平台还包括至少一个通人管道,至少一个通人管道的一端位于水面以上,另一端连通水平轴水轮发电机或其中一个受力支撑件或受力阻挡件,使得人能够通过至少一个通人管道到达水面以下进行维修或固定操作。
于本发明的第一方面的一实施例中,总成平台还包括至少一个鼓风机和一个通风管,通风管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,通风管从水面以上通到水面以下以使水面下的工作区内能够进行换风。
于本发明的第一方面的一实施例中,总成平台还包括至少一个抽水泵和至少一根排水管,排水管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,排水管从水面以上通到水面以下,抽水泵抽取水面以下的工作区内的积水并通过排水管排出到水面以上。
于本发明的第一方面的一实施例中,总成平台还包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构,人员可以进入固定组件箱的内部进行工作。
于本发明的第一方面的一实施例中,每个固定组件箱具有密封装置和固定组件,固定组件包括至少一个固定螺栓或至少一个千斤顶,密封装置对应地设于固定组件处。
于本发明的第一方面的一实施例中,每一列固定桩朝水平轴水轮发电机的一侧设置有侧板。
于本发明的第一方面的一实施例中,总成平台的每一根固定桩在最低潮位线以上的区域都设有混凝土保护装置。
于本发明的第一方面的一实施例中,大型潮流能发电装置包括如本发明第四方面所提供的栅栏。
于第二方面,本发明还提供一种大型潮流能发电装置,包括如第一方面任一实施例所述的总成平台、至少一个水平轴水轮发电机以及至少一个悬挂支撑柱。至少一个水平轴水轮发电机可分离地安装于总成平台中。至少一个悬挂支撑柱为密闭中空结构,悬挂支撑柱的一端位于水面以上,悬挂支撑柱的另一端连通水平轴水轮发电机或受力阻挡件或受力支撑件,使得人能够通过悬挂支撑柱到达水面以下进行维修或固定操作。
于本发明的第二方面的一实施例中,大型潮流能发电装置还包括至少一个连接件,至少一个连接件横向或纵向地连接悬挂支撑柱位于水面以上的一端和总成平台。
于本发明的第二方面的一实施例中,总成平台包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构,悬挂支撑柱的数量为至少两个,至少两个悬挂支撑柱的另一端分别连通对应的固定组件箱,从而人员能通过悬挂支撑柱到达固定组件箱的内部。
于本发明的第二方面的一实施例中,悬挂支撑柱的数量为三个,两个悬挂支撑柱的另一端分别连通位于水平轴水轮发电机两侧的受力阻挡件或受力支撑件,另一个悬挂支撑柱的另一端连通水平轴水轮发电机,三个悬挂支撑柱位于水面以上的端相互连接。
于本发明的第二方面的一实施例中,大型潮流能发电装置包括如本发明第四方面所提供的栅栏。
于第三方面,本发明还提供一种大型潮流能发电装置,包括:
至少两个总成平台,每个总成平台包括至少四根固定桩,所述至少四根固定桩通过支架连成一体且围绕形成一个安装空间,每根固定桩的一端打桩固定于海床,另一端延伸到水面以上,所述至少四根固定桩沿着水流方向分左右两列依次布放,其中每一列至少两根固定桩沿着水流方向布放;
至少三个水平轴水轮发电机,每个总成平台的安装空间内可分离地安装有至少一个水平轴水轮发电机;
其中,所述至少两个总成平台沿着水流方向左右布放,两个总成平台之间的间隔和一个水平轴水轮发电机的叶轮直径相匹配,使得额外的至少一个水平轴水轮发电机能够安装于两个总成平台之间。
于本发明的第三方面的一实施例中,每个总成平台包括至少两个受力阻挡件和至少两个受力支撑件,至少两个受力阻挡件分别固定于对应的固定桩或支架上且位于水面以下水平轴水轮发电机沿水流方向的左右两侧。至少两个受力支撑件的一端分别安装在水平轴水轮发电机沿水流方向的左右两侧,另一端分别抵靠在对应的受力阻挡件上,以抵挡水流对水平轴水轮发电机的冲击力。
于本发明的第三方面的一实施例中,总成平台还包括至少两组避震装置,每组避震装置设置于受力支撑件与受力阻挡件之间。
于本发明的第三方面的一实施例中,总成平台具有至少两个导槽,分别设置于对应的固定桩或支架上且位于水平轴水轮发电机沿水流方向的左右两侧, 导槽的一端位于水面以上,另一端通向水面以下,至少两个受力阻挡件分别固定于对应的导槽的另一端。
于本发明的第三方面的一实施例中,每个总成平台还包括至少两组用于安装或固定栅栏的栅栏导槽,所述至少两组栅栏导槽分别设置在水平轴水轮发电机的上下游两侧,每组栅栏导槽都从水面以上通到水面以下。
于本发明的第三方面的一实施例中,每个总成平台包括至少一个通人管道,至少一个通人管道的一端位于水面以上,另一端连通水平轴水轮发电机或其中一个受力支撑件或受力阻挡件,使得人能够通过至少一个通人管道到达水面以下进行维修或固定操作。
于本发明的第三方面的一实施例中,每个总成平台包括至少一个鼓风机和一个通风管,所述通风管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,通风管从水面以上通到水面以下以使水面下的工作区内能够进行换风。
于本发明的第三方面的一实施例中,所述每一个总成平台包括至少一个抽水泵和至少一根排水管,排水管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,排水管从水面以上通到水面以下,抽水泵抽取水面以下的工作区内的积水并通过排水管排出到水面以上。
于本发明的第三方面的一实施例中,每个总成平台包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构,人员可以进入固定组件箱的内部进行工作。
于本发明的第三方面的一实施例中,每个固定组件箱具有密封装置和固定组件,固定组件包括至少一个固定螺栓或至少一个千斤顶,密封装置对应地设于固定组件处。
于本发明的第三方面的一实施例中,每一列固定桩朝水平轴水轮发电机的一侧设置有侧板。
于本发明的第三方面的一实施例中,每个总成平台的每一根固定桩在最低潮位线以上的区域都设有混凝土保护装置。
于本发明的第三方面的一实施例中,潮流能发电装置还包括至少一个悬挂支撑柱,悬挂支撑柱为密闭中空结构,悬挂支撑柱的一端位于水面以上,悬挂支撑柱的另一端连通水平轴水轮发电机或受力阻挡件或受力支撑件,使得人能够通过悬挂支撑柱到达水面以下进行维修或固定操作。
于本发明的第三方面的一实施例中,大型潮流能发电装置还包括至少一个连接件,至少一个连接件横向或纵向地连接悬挂支撑柱位于水面以上的一端和总成平台。
于本发明的第三方面的一实施例中,每个总成平台包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构,悬挂支撑柱的数量为至少两个,至少两个悬挂支撑柱的另一端分别连通对应的固定组件箱,从而人员能通过悬挂支撑柱到达固定组件箱的内部。
于本发明的第三方面的一实施例中,悬挂支撑柱的数量为三个,两个悬挂支撑柱的另一端分别连通位于水平轴水轮发电机两侧的受力阻挡件或受力支撑件,另一个悬挂支撑柱的另一端连通水平轴水轮发电机,三个悬挂支撑柱位于水面以上的端相互连接。
于本发明的第三方面的一实施例中,大型潮流能发电装置包括如本发明第四方面所提供的栅栏。
于第四方面,本发明还提供一种潮流能发电装置,包括至少两个栅栏,分别设置于水平轴水轮发电机的上下游两侧,每个栅栏沿水流方向的宽度大于或等于8厘米。
于本发明的第四方面的一实施例中,潮流能发电装置包括如本发明第一方面或第二方面任一实施例所述的总成平台。
于本发明的第四方面的一实施例中,潮流能发电装置包括如本发明第二方面任一实施例所述的悬挂支撑柱。
于本发明的第四方面的一实施例中,潮流能发电装置采用如本发明第三方面任一实施例所述的潮流能发电装置。
于第五方面,本发明还提供一种大型潮流能发电装置,包括:
一个总成平台,固定在海床上;
水平轴水轮发电机,可分离地置入所述总成平台内;
至少两个受力阻挡件,设置于总成平台上且位于水面以下;
至少两个受力支撑件,所述两个受力支撑件的一端分别安装在所述水平轴水轮发电机沿水流方向的左右两侧,另一端分别抵靠在所述总成平台左右两侧的两个受力阻挡件上,以抵挡水流对所述水平轴水轮发电机的冲击力;
至少一个通人管道,一端与水平轴水轮发电机的内部连通,另一端位于水面以上,或者一端通向总成平台的水面以下工作区域,另一端通向水面以上,从而使得人员能够进入到水面以下的工作区域内进行工作;
至少一个鼓风机;
至少一个通风管,所述通风管可固定或可拆卸的安装在所述通人管道的内侧或外侧,所述通风管的一端通向水面以上,另一端通向水面以下,当人员需要进入水面以下的工作区内工作时,启动鼓风机对水面以下的工作区域内进行换风,以保障工作人员生命安全
于本发明的第五方面的一实施例中,包括至少一个抽水泵和至少一根排水管,排水管可固定或可拆卸地安装在所述通人管道的内侧或外侧,所述排水管的一端通向水面以上,另一端通向水面以下的工作区域,当水面以下的工作区域内部出现漏水时,抽水泵抽取内部的积水通过排水管排出到水面以上,以保障设备或工作人员生命安全。
于本发明的第五方面的一实施例中,大型潮流能发电装置包括如本发明第四方面任一实施例所述的栅栏。
综上所述,本发明通过将四根固定桩和支架连在一起形成安装空间,然后水平轴水轮发电机固定于安装空间内,而不是像现有技术一样将水平轴水轮发电机安装于框架内,大幅度降低了钢材的使用,降低了制造和安装成本。并且,本发明通过设置位于水平轴水轮发电机两侧的受力支撑件和受力阻挡件,能够将水平轴水轮发电机受到的水流的推力均衡地传递到两侧,从而分散给整个总成平台,使得整个总成平台能够承载更大功率的单个水平轴水轮发电机,大幅度降低了潮流能发电装置的发电成本。特别地,本发明的水平轴水轮发电机在水中具有“固定点”,因此避免了现有技术中水平轴水轮发电机在水流巨大的推力作用下,因为晃动产生共振现象从而容易损坏的问题。通过采用本实施例提供的大型潮流能发电装置及其总成平台,能够真正使得潮流能发电装置实现大型化,将潮流能发电的成本降低到低于火力发电的成本,从而真正实现潮流能发电的商业推广和运用。
为让本发明的上述和其它目的、特征和优点能更明显易懂,下文特举较佳实施例,并配合附图,作详细说明如下。
附图说明
图1所示为根据本发明第一实施例提供的大型潮流能发电装置的俯视图。
图2所示为根据本发明第一实施例提供的大型潮流能发电装置的侧视图。
图3所示为本发明提供的受力支撑件和受力阻挡件在不同实施例下的截面示意图。
图4所示为根据本发明第一实施例提供的大型潮流能发电装置的安装示意图。
图5所示为根据本发明第二实施例提供的大型潮流能发电装置的局部俯视图。
图6所示为根据本发明第二实施例提供的大型潮流能发电装置的局部侧视图。
图7所示为根据本发明第二实施例提供的大型潮流能发电装置的内模块的俯视图。
图8所示为根据本发明第二实施例提供的大型潮流能发电装置的安装示意图。
图9所示为根据本发明第三实施例提供的大型潮流能发电装置的安装示意图。
图10所示为根据本发明第四实施例提供的大型潮流能发电装置的安装示意图。
图11所示为根据本发明第五实施例提供的大型潮流能发电装置的安装示意图。
图12所示为根据本发明第六实施例提供的大型潮流能发电装置的俯视图。
图13所示为根据本发明第七实施例提供的大型潮流能发电装置的俯视图。
图14所示为根据本发明第八实施例提供的栅栏的示意图。
图15所示为根据本发明第九实施例提供的大型潮流能发电装置的示意图。
图16所示为根据本发明第九实施例提供的大型潮流能发电装置的安装示意图。
图17所示为根据本发明第十实施例提供的大型潮流能发电装置的示意图。
具体实施方式
图1所示为根据本发明第一实施例提供的大型潮流能发电装置的俯视图。图2所示为根据本发明第一实施例提供的大型潮流能发电装置的侧视图。图3所示为根据本发明第一实施例提供的受力支撑件和受力阻挡件的截面示意图。图4所示为根据本发明第一实施例提供的大型潮流能发电装置的安装示意图。图2中右边圆圈为左边圆圈标识处的放大示意图。如图1-图4所示,于第一实施例中,大型潮流能发电装置包括总成平台1和至少一台水平轴水轮发电机2,至少一台水平轴水轮发电机2安装于总成平台1中。
于本实施例中,总成平台1包括至少四根固定桩11、至少两个受力阻挡件12、至少两个受力支撑件13以及支架14。每根固定桩11的一端打桩固定于海床F,另一端延伸到水面P以上。至少四根固定桩11通过支架14连成一体,四根固定桩11和支架14一起围绕形成一个安装空间15。四根固定桩11沿着水流方向D分左右两列布放,其中每一列至少两根固定桩11沿着水流方向D依次布放。具体而言,至少四根固定桩11分为两组(即两列),每组包括至少两根固定桩11。每组内的至少两根固定桩11的横截面过中心点连成的线基本平行于水流方向D(可允许有些微偏差)。由于每组固定桩11排成了平行于水流方向D的一列,因此位于下游的固定桩11承受的水流冲击力会在位于上游的固定桩11的阻挡后大大减小。如图1所示,当涨潮的时候,水流方向为D,当落潮的时候,水流方向变为D’。本文中所提及的“左”和“右”,是相对于水流方向而言的左右两侧。具体而言,如图1所示方向看去,即从水面之上俯视,两列固定桩11分别位于左侧和右侧。
于本实施例中,支架14包括多个刚性杆件,每个刚性杆件连接两根固定桩11。整个总成平台1承受的力是靠支架14在固定桩11之间进行传递从而得到分解。通过设置支架14,至少四根固定桩11一起形成一个整体,单根固定桩11受到的力能够有效地传递到其它固定桩11,从而使得整个总成平台1的受力分布均衡。于本实施例中,固定桩11的水下部分和水上部分均设有支架14进行连接。当潮流能发电装置所在的海域比较深时,固定桩11会比较长,可以在水下多处设置支架14,这样可以使固定桩11之间的连接更加牢靠,能够更加有效地进行力的分散。然而,本发明对此不作任何限定,支架14的连接位置和连接数量可随具体要求进行设置。
于实际应用中,每根固定桩11不一定要完全垂直于海床F进行安装。于本实施例中,位于迎水侧或者落水侧(即如图1所示的最下方和最上方)的固定桩11可倾斜地插入海床F中。每根倾斜插入的固定桩11能抵抗水流冲击力的能力是垂直设置的固定桩的1.5倍左右,即倾斜设置的固定桩11能承载分散更大的水流冲击力。
于本实施例中,大型潮流能发电装置的总成平台1可一共包括八根固定桩11,四根固定桩11位于水平轴水轮发电机2的左侧,四根固定桩11位于水平轴水轮发电机2的右侧。位于左侧或右侧的四根固定桩11沿着水流方向D依次布置。本发明对固定桩11的具体数量也不做任何限定。于其它实施例中,固定桩的数量可为4个、6个或12个。通过设置更多的固定桩11,水流带给水平轴水 轮发电机2的冲击力能够传递给更多的固定桩11,因而水流冲击力能够有效地得到分散,从而使得整个潮流能发电装置能够承受和抵抗更大的水流推力,因此也提高了总成平台1承载单个更大规模的水平轴水轮发电机2的能力。换言之,本发明实施例提供的总成平台1能够支撑更大功率的水平轴水轮发电机2,提高了单个水轮机叶轮加上单个发电机的功率的上限,从而实现潮流能发电装置的商业推广和运用。另外,随着固定桩11数量的增多,可以对应减小每个固定桩11的直径,从而减小固定桩11阻挡水流的截面,提高水平轴水轮发电机2对水流的利用率,使得水平轴水轮发电机2的发电效率得到提升。
具体而言,以本申请背景技术部分所提及的现有的海上风力发电装置为例,该装置能承载的单机装机功率最大为5MW,但是需要最大直径大于6m的固定桩才能实现承载。而本实施例通过至少四根固定桩11和支架14组成一个整体从而将受到的水流推力进行分散,每根固定桩只需要做到直径为1.3m即可承载单机装机功率为5MW的水平轴水轮发电机,因此固定桩的直径能够得到大幅度降低。每根固定桩的制作难度和成本也随之降低。另外,单根固定桩需要固定在海床上的安装过程会非常繁琐。在安装期间,单根固定桩的周围需要先设置多根辅助桩形成的打桩平台,然后单根固定桩完成安装固定后,再派人派船去撤掉辅助打桩平台,甚至牵涉到水下作业,这样导致固定桩的安装成本非常高昂。然而,本实施例采用至少四根彼此相连的固定桩,形成天然的打桩平台。无需另外设置辅助打桩平台,大幅度降低了固定桩的安装成本。因此,四根直径为1.3m的固定桩的制造成本和安装成本之和都远远小于一根直径为6m的固定桩的制造成本和安装成本。
如果本实施例的每根固定桩做到3m直径,则可承载装机功率高达20MW的水平轴水轮发电机,打破了现有单机装机功率的上限,真正做到了将单机装机功率做大。现有的潮流能发电装置的最大单机装机功率仅为2MW,要达到20MW的发电量,需要运行高达十台的水平轴水轮发电机,并且需要设置至少十个总成平台进行安装。但是本发明第一实施例的大型潮流能发电装置,仅需要设置一台水平轴水轮发电机和一个总成平台即可实现20MW的发电量,大幅度降低了成本,使得潮流能发电装置的商业化运用真正成为可能。
潮流能发电装置的成本基本由两部分构成,一个是发电机的制造成本和安装成本,另一个是总成平台的制造成本和安装成本。举例而言,一台2.5MW的水平轴水轮发电机的制造成本和安装成本为2000万,两台2.5MW的水平轴水轮发电机的制造成本和安装成本为4000万,而一台5MW的水平轴水轮发电机 的制造成本和安装成本仅为2600万。换言之,不考虑总成平台的制造成本和安装成本差额,光水平轴水轮发电机的成本而言,运行更大功率的水平轴水轮发电机将大幅度降低每度电的成本,更不用说本实施例的总成平台的制造成本和安装成本也远远低于现有技术的总成平台的制造成本和安装成本。
于本实施例中,至少两个受力阻挡件12固定于固定桩11或支架14上,受力阻挡件12位于水面P以下水平轴水轮发电机2沿水流方向D的左右两侧。具体而言,本实施例的大型潮流能发电装置的总成平台有8根固定桩,两个受力阻挡件12分别设置在如图1所示左边中间两根固定桩11上和右边中间两根固定桩11上且位于固定桩11朝向水平轴水轮发电机2的一侧。若潮流能发电装置仅具有四根固定桩,则受力阻挡件可安装于连接两根固定桩的支架上。换言之,受力阻挡件12可直接或间接地安装在固定桩11上。
于本实施例中,至少两个受力支撑件13的一端分别安装在水平轴水轮发电机2沿水流方向D的左右两侧,另一端分别抵靠在对应的受力阻挡件12上。于本实施例中,以图1中位于左侧的受力支撑件13为例,受力支撑件13的一端指的是右端,受力支撑件13的另一端为左端。以图1中位于右侧的受力支撑件13为例,受力支撑件13的一端指的是左端,受力支撑件13的另一端为右端。
本实施例的受力支撑件13和受力阻挡件12相结合以抵挡水流对水平轴水轮发电机2的冲击力。具体而言,如图1所示,水流从下往上沿水流方向D冲向水平轴水轮发电机2,由于两个受力支撑件13的一端分别固定在水平轴水轮发电机2的两侧,可以直接将水流对水平轴水轮发电机2的推力进行两侧的传递和分解。推力先后通过受力支撑件13、受力阻挡件12和支架14被均衡地分配到每根固定桩11上,所有的固定桩11共同受力。同时,由于两个受力支撑件13的另一端分别受到受力阻挡件12的“阻挡”,受力阻挡件12是固定在支架14或固定桩11上,因此受力阻挡件12会对受力支撑件13产生一个如图1方向看去从上往下的“阻挡力”,不同的力之间产生的效果发生抵消,从而达到一个平衡,进而保证水平轴水轮发电机2在水中的稳定,从而提高了水平轴水轮发电机2能够承受水流推力的上限。
于现有技术中,水平轴水轮发电机是通过单根承载桩固定于海床,单根承载桩将承受水流对水平轴水轮发电机全部的冲击力。在这个过程中产生的弯矩和剪切力将非常大,为了确保承载桩不超负荷,对水平轴水轮发电机的单机装机规模设置了上限。然而,本实施例的总成平台,在整个发电装置的“腰部”设置了至少两个受力点,有效地将水流对水平轴水轮发电机的冲击力进行横向 的分散。由于潮流能发点装置是利用水流的动能进行发电,水流的推力越大,发电量越大,因此,本实施例的潮流能发电装置能够承载更大功率的水平轴水轮发电机。
于本实施例中,受力阻挡件12的截面为凹型。然而,本发明对此不作任何限定。于其它实施例中,受力阻挡件12的截面可为凸型或锥形。本发明对受力阻挡件12和受力支撑件13的具体形状不做任何限定,受力阻挡件12只需和受力支撑件13的一端形成卡合关系即可。图3简要地示意了一些受力阻挡件12和受力支撑件13可能的截面形状。然而,本发明的受力阻挡件12和受力支撑件13的实际形状不限于此。于实际应用中,受力支撑件13优选具有弧形或其它形状的流线型外观。通过这种设置,尽可能地减少受力支撑件13在水中受到的阻力。
本实施例的受力阻挡件12和受力支撑件13可通过千斤顶或者固定螺栓进行固定。然而,本发明对此不作任何限定。于另一实施例中,受力阻挡件12和受力支撑件13的另一端可以实现过盈配合。具体而言,当将受力支撑件13安装在受力阻挡件12上时,无需额外配置千斤顶或者固定螺栓即可将受力支撑件13和受力阻挡件12完全卡牢,二者的固定不会出现松动。安装的时候也对应地无需安装人员进入水下进行安装操作,也因此无需额外设置通人管。在这种情况下,受力阻挡件12和受力支撑件13的制造精密度要求高,受力支撑件13的截面可以设置为特定的外形从而和受力阻挡件12卡合牢固(例如图3最右侧所示的形状)。水流的冲击力非常巨大,位于左侧和右侧的受力支撑件和受力阻挡件,一旦其中一侧精度不匹配,水平轴水轮发电机容易倾斜。优点是在安装过程中受力支撑件和受力阻挡件的连接只需要依靠卡合关系,不需要额外地再次固定和调整。在受力阻挡件和受力支撑件靠卡合关系固定的情况下,也可以在受力支撑件的下方安装千斤顶,当需要从水中自上而下吊出水平轴水轮发电机时,只需要抬高千斤顶,将受力支撑件顶起即可解除受力支撑件和受力阻挡件的卡合关系,从而使得水平轴水轮发电机可以吊出水面。
于本实施例中,受力阻挡件12和受力支撑件13的数量均为两个。然而,本发明对此不作任何限定。于其它实施例中,受力阻挡件和受力支撑件的数量可均为四个,水平轴水轮发电机沿水流方向的左右两侧可各有两个受力阻挡件和受力支撑件。于另一实施例中,受力支撑件13的数量可为两个,受力阻挡件12的数量可为四个,每两个受力阻挡件12为一组固定在受力支撑件的另一端上。于本实施例中,受力支撑件13的长度方向为垂直于水流方向D且平行于水平面 P的方向,这样设置既减小受力支撑件1的用钢量也减小受力支撑件1产生的弯矩。本发明对此也不作任何限定。于其它实施例中,受力支撑件的长度方向可垂直于水流方向,但是和水平面可不平行,即受力支撑件可倾斜设置。受力支撑件13越倾斜设置,受力支撑件13的长度将会变长,用钢量将会变大,并且产生的弯矩也会增加。因此,受力支撑件13和受力阻挡件12的结合端需要设置于水面以下。
于本实施例中,两个受力支撑件13的一端是直接安装于水平轴水轮发电机2的发电机部分且位于左右两侧。然而,本发明对此不作任何限定。于其它实施例中,水平轴水轮发电机可具有悬挂支撑柱,则两个受力支撑件13的一端可以安装在悬挂支撑柱上,且仍然位于水平轴水轮发电机2的两侧。换言之,受力支撑件的一端是直接或间接地安装在水平轴水轮发电机2上,从而朝两侧分解水平轴水轮发电机2受到的力。优选地,两个受力支撑件13固定于水平轴水轮发电机2两侧的位置离水平轴水轮发电机越近越好,越远则分解和传递力的作用越弱,同时增加了悬挂支撑柱产生的弯矩。
于实际安装过程中,水平轴水轮发电机2和受力支撑件13在岸上进行焊接固定,组装形成内模块。固定桩11的雏形、支架14和受力阻挡件12也先在岸上相互焊接固定连接,之后将其运至安装水域,分别对至少四根固定桩11进行打桩操作(包括但不限于在海床上进行钻孔、打桩嵌入基岩层、在桩内灌注混凝土形成钢筋混凝土灌注桩),进而完成了总成平台1的安装。之后将内模块从水面上自上而下吊入总成平台1的安装空间15内,然后完成受力支撑件13和受力阻挡件12的固定,即完成整个潮流能发电装置的安装。于本实施例中,潮流能发电装置及其总成平台所有的制造和安装动作都可以在水面以上完成,杜绝了水下作业,降低了施工难度,提高了施工人员的安全性,也大幅度减少了施工安装成本。
关于本实施例中每根固定桩11如何固定于海床F上,可以采用本发明人发明的另外一个中国专利(公告号CN105401564)披露的打桩方式进行打桩,也可以采用现有的其它打桩方式,在此不展开进行描述。本发明对此也不作任何限定。需要注意的是,本实施例仅固定桩的打桩方式可以和CN10540156中披露的打桩方式一致,但是整个潮流能发电装置的结构和安装方式与CN10540156中披露的结构和安装方式有本质的不同。
首先,本发明人发明的CN10540156中的水平轴水轮发电机是先安装在内框架里,之后将内框架插入外框架中。内框架和外框架的设置会导致用钢量大大 增加,成本大幅度攀升。在将本发明人之前发明的潮流能发电装置投入实际应用后,发明人发现水流产生的推力是巨大无法想象的,最大能产生高达2000-3000吨力的推力。因此只能通过加大内框架的重量,靠自身重力带来的摩擦来抵消水流对水轮发电机的推力,这样就导致用钢量和成本急剧上升。本实施例完全摒弃了框架的使用,整个总成平台,除了在灌注混凝土形成固定桩过程中需要用到钢筋笼,受力支撑件、受力阻挡件和支架用到钢材以外,其他部分完全不需要钢材。整个总成平台的钢材消耗量几何层级地减少,大幅度降低了制造成本。
本发明人经过实际应用比对发现,实施本发明人之前发明的安装方法和结构,一台单机装机规模为200KW的水平轴水流发电机,叶轮的直径为5.4m,叶轮的截面为22.9m 2,水轮发电机将承受水流23吨力的推力,此时,内框架需要高达230多吨,才能保障水轮发电机的安全运行。然而,本实施例的潮流能发电装置整个总成平台的重量仅需要做到125吨(如果除去中空的受力支撑件、中空的发电机机舱等产生的浮力,在水中实际只有25吨的重力),即可平稳运行单机装机规模为1.5MW的水平轴水轮发电机,其叶轮直径为15m,叶轮的截面为177m 2,水轮发电机会承受水流177吨力的推力。如果采用本发明人之前发明的安装方法和结构,需要高达1800吨的框架才能承载1.5MW的水平轴水轮机,而这个重量的框架无论是从技术还是从成本角度而言,都根本不可能实现。因此,光框架这个问题就限制了现有水平轴水轮发电机单机规模的做大。
其次,CN10540156中的水平轴水轮发电机是通过中心转轴可转动地固定在内框架的最上方和最下方。在水流巨大的推力作用下,水平轴水轮发电机在运行过程中很容易产生振动,发电机规模越大,振动就越厉害。剧烈的振动会导致水平轴水轮发电机内部的元器件产生共振从而发生损坏。因此,在将本发明人之前发明的潮流能发电装置投入实际应用后,发现采用CN10540156中的安装方式,只能安全运行200KW或300KW的水平轴水轮发电机,单机规模如果达到1MW以上,水平轴水轮发电机将非常容易损坏,这使得水平轴水轮发电机的单机规模无法突破。然而,本实施例提供的潮流能发电装置在水平轴水轮发电机的腰部或者腰部附近设有至少两个“束缚点”,水平轴水轮发电机是直接牢固地和受力支撑件进行固定,然后受力支撑件也牢固地和受力阻挡件固定,受力阻挡件和支架与固定桩之间也是牢固的固定关系。换言之,水平轴水轮发电机和总成平台是牢固的固定关系,没有元器件会在水中发生超出安全范围的震动, 避免了共振的问题。因此本实施例提供的潮流能发电装置可以平稳运行更大装机规模的水平轴水轮发电机。
于本实施例中,总成平台1具有至少两个导槽121,分别位于水平轴水轮发电机2沿水流方向D的左右两侧,导槽121从水面以上通向水面以下,至少两个受力阻挡件12分别固定于对应的导槽121的底端。于本实施例中,导槽121可设置于对应的固定桩11或支架14上且位于固定桩11或支架14朝向水平轴水轮发电机2的一侧。导槽121的一端位于水面P以上,另一端可位于和水平轴水轮发电机2的中心点同一水平的位置或者比中心点偏下的位置。导槽121的作用是方便安装或固定受力支撑件13。在安装受力支撑件13时,受力支撑件13的一端可以从水上沿着导槽121滑到水下,然后和位于导槽121底端的受力阻挡件12进行固定。
于本实施例中,为了有效地减少海洋异物(例如海洋垃圾或者浮冰)对水平轴水轮发电机2的损害,因此需要在水平轴水轮发电机2的上游和下游均设置栅栏。由于海洋垃圾较多,当栅栏使用一段时间之后需要定期清理表面垃圾,才能够确保水流一直顺畅地涌入水平轴水轮发电机2而不被垃圾阻挡,保障发电效率。另外,由于水流湍急,有些垃圾比较尖锐,即便是采用钢丝制作栅栏,仍然会存在损坏问题,因此栅栏需要经常维修和更换。现有的栅栏清理、安装和维修人员必须潜到水里进行作业,操作难度高,效率低,并且由于潮流能发电机周围水流冲撞容易造成漩涡,维修和清理也存在危险。
于本实施例中,总成平台1还包括至少两组用于安装或固定栅栏的栅栏导槽16,两组栅栏导槽16分别设置于水平轴水轮发电机2的上下游两侧(如果水流方向如图1中的D所示,则图1的下方为上游,图1的上方为下游),每组栅栏导槽16都从水面以上通到水面以下。于本实施例中,每组栅栏导槽16包括两个栅栏导槽,一组栅栏导槽16位于图1中上游两根固定桩11(图1中最下方的两根固定桩)上游的一侧,另一组栅栏导槽16位于图1中下游两根固定桩11(最上方的两根固定桩)下游的一侧。于实际应用中,栅栏的左右两个侧边可沿着一组栅栏导槽16从上往下插入到栅栏导槽16中,之后依靠自身的重力作用滑行到底端,从而完成栅栏的安装和固定。通过设置栅栏导槽16,使得栅栏的安装更加简便,不需要进行海里的安装作业,直接进行海面上操作即可完成栅栏的安装。特别地,需要对栅栏进行清理或更换时,可以沿着栅栏导槽16从下往上拉出栅栏,人员只需要在水面上进行操作。因此,栅栏导槽16的设置也 方便了栅栏的清理和更换工作。通过设置栅栏导槽16,降低了安装栅栏和维修更换的成本。本实施例对栅栏的具体类型不作任何限定。
于本实施例中,总成平台1包括至少一个通人管道17,至少一个通人管道17从水面以上通到水面以下,使得人能够通过通人管道17到达水面以下进行维修或固定操作。通人管道17的一端位于水面P以上,另一端位于水面P以下连通水平轴水轮发电机2或者受力支撑件13或者受力阻挡件12。于本实施例中,通人管道17的数量为两个,两个通人管道17分别沿支架14进行设置。于一实施例中,通人管道17可分别连通受力支撑件13,人员可以通过通人管道17到达受力支撑件13内,对受力支撑件13和受力阻挡件12之间进行固定安装。然而,本发明对此不做任何限定。于其它实施例中,通人管道17可以设置于水平轴水轮发电机2两侧的一个固定桩11内,且分别连通受力支撑件13或受力阻挡件12。于另一实施例中,通人管道17也可以设置于支架14内。
于本实施例中,两个受力支撑件13可为中空结构,人员可以通过通人管道17和受力支撑件13到达水平轴水轮发电机2的内部,对水平轴水轮发电机2内部进行维修操作(比如机油的更新、齿轮的更换、密封件的更换等)。然而,本发明对此不作任何限定。于其它实施例中,总成平台可仅具有一个通人管道,通人管道也设置于固定桩内,人员可通过通人管道到达一侧的受力支撑件,对一侧的受力支撑件和受力阻挡件进行固定安装,也可经过受力支撑件到达水平轴水轮发电机的内部,对水平轴水轮发电机进行维修操作,还可以依次通过一侧的受力支撑件、水平轴水轮发电机、另一侧的受力支撑件,对位于另一侧的受力支撑件和受力阻挡件进行固定安装。于又一实施例中,总成平台可仅具有一个通人管道,通人管道可以设置于固定桩内并且可连通受力阻挡件,安装人员可以通过通人管道到达受力阻挡件内,对受力支撑件和受力阻挡件之间进行固定安装。于又一实施例中,总成平台可设置专门的通人管道,直接从水面之上连通水平轴水轮发电机的内部。
于本实施例中,总成平台1还包括至少一个鼓风机181和一个通风管182,通风管182可固定或可拆卸地沿通人管道17内或沿通人管道17外进行布置,通风管182从水面P以上通到水面P以下以使水面下的工作区内能够进行换风。现有的潮流能发电装置没有考虑过水下安装或者维修的情况。本发明人之前考虑过水下维修,但是忽视了由于内部的机器长时间运行,机器发热产生的高温也会伴随产生有毒有害气体和二氧化碳浓度过高的问题。如果需要进行水下作业,人员需要长时间呆在水下,很容易发生缺氧或者二氧化碳中毒等情况。本 实施例的鼓风机181和通风管182构成了新风系统,大大保障了进入水下的维修人员或者安装人员的生命安全。当人员需要进入水面以下的工作区内进行工作时,可启动鼓风机对水面以下的工作区内进行换风。于具体应用中,新风系统可具有更复杂的结构,比如具有独立的送风系统和排风系统等,在此不展开进行赘述。
于本实施例中,总成平台1还包括至少一个抽水泵183和至少一根排水管184,排水管184可固定或可拆卸地沿通人管道17内或沿通人管道17外进行布置,排水管184从水面P以上通到水面P以下,抽水泵183抽取水面以下的工作区内的积水并通过排水管184排出到水面以上。由于整个潮流能发电装置的大部分都是位于水中,在长久的运行后,密封圈容易发生松动,很难保证不会发生密封圈处漏水的情况。如果没有任何防护措施,维修人员或安装人员从通人管道17进入水下工作区域的话,很可能会面临生命危险。通过设置抽水泵183和排水管184,大大保障了人员的生命安全。于本实施例中,当人员需要进行水下工作前,启动抽水泵183先运行一段时间,观察排水管184是否有积水排出。人员可以直到排水管184没有明显积水排出才进入通人管道17。在人员进行水下工作时,抽水泵183一直保持工作直到人员完成工作回到水面以上。然而,本发明对抽水泵的工作形式不作任何限定。于其它实施例中,抽水泵183可定期运行以抽取内部的积水并通过排水管184排出到水面以上,从而避免积水损害元器件,并且保证工作人员的生命安全。
于本实施例中,通风管182、排水管184、通人管道17可均沿支架14或者固定桩11设置,并且这些管道可都连通受力支撑件13的内部。并且通风管182和排水管184可以沿着中空的受力支撑件13进行布置,一直到达水平轴水轮发电机2的内部。然而,本发明对此不作任何限定。于其它实施例中,可在固定桩11内设置专门的通风管182、排水管184、通人管道17从水上通到水下。
于本实施例中,总成平台1还可包括至少两个固定组件箱18,每个固定组件箱18对应于受力阻挡件12进行设置,固定组件箱18为中空结构,人员可以进入固定组件箱18的内部进行工作。固定组件箱18可装在受力支撑件13抵靠在受力阻挡件12的一端,用于将受力阻挡件12和受力支撑件13进行固定连接。于本实施例中,每个固定组件箱18连通通人管道17。换言之,本实施例的通人管道17是直接通到固定组件箱18的内部而不是直接连通受力支撑件13。
于本实施例中,每个固定组件箱18具有密封装置185和固定组件186,固定组件186包括至少一个固定螺栓或至少一个千斤顶,密封装置185对应地设 于固定组件186处。于本实施例的潮流能发电装置的安装过程中,在岸上将水平轴水轮发电机2、至少两个受力支撑件13和至少两个固定组件箱18焊接连接好形成内模块。在固定桩11完成在海床F上的打桩固定后,将内模块自上而下吊入位于水中的安装空间15内,固定组件箱18可沿导槽121滑入导槽121的底端。随后人员从通人管道17进入到固定组件箱18内部,通过调节固定组件186(比如拧紧固定螺栓或者顶起千斤顶),将固定组件箱18和受力阻挡件12卡紧,从而实现受力阻挡件12和受力支撑件13的固定。至此,整个内模块和总成平台1完成固定,整个潮流能发电装置完成安装。然而,本发明对此不作任何限定。本实施例也可不具有固定组件箱18,可以直接设置密封装置185和固定组件186将受力支撑件13和受力阻挡件12固定在一起。
当水流沿水流方向D冲向水平轴水轮发电机2时,受力支撑件13受到巨大的从图1方向看过去的由下方往上方的冲击力,连带固定组件箱18会被推动抵靠在受力阻挡件12从图1方向看过去的上侧。在实际制造过程中,很难保证固定组件箱18的尺寸能完全和受力阻挡件12的定位槽的尺寸完全匹配。因为公差的存在,所以固定组件箱18和受力阻挡件12之间会存在间隙。为了避免水平轴水轮发电机2发生晃动,安装人员可以通过通人管道17进入到固定组件箱18内,开始调节固定组件186(比如拧紧固定螺栓或者顶起千斤顶),从而使得固定组件186的顶端牢牢抵靠在受力阻挡件12的定位槽的内壁上。此时,固定组件箱18被卡死在受力阻挡件12中,避免了水平轴水轮发电机2的晃动。无论涨潮还是落潮,水平轴水轮发电机2都牢牢地被定位,不会产生超出可接受范围的振动现象。在这个过程中,鼓风机181一直工作,从通风管182送入新鲜的空气。并且抽水泵183也可以一直工作,从排水管184排出可能的积水,从而保障人员的生命安全。于另一实施例中,当不设置固定组件箱18,通人管道17也可以直接通向受力支撑件13或者受力阻挡件12内部,从而完成受力支撑件13和受力阻挡件12的固定连接。
于本实施例中,每一列固定桩11朝水平轴水轮发电机2的一侧设置有侧板19。侧板19能够形成水道从而起到整流作用,即可以将水流聚集,更好地导向水平轴水轮发电机2,从而提高发电效率。于另一实施例中,从图2所示的方向看去,上下左右四侧可都设有侧板,从而形成水道将水集中引导冲向水平轴水轮发电机2。
如图4所示,于本实施例中,总成平台1的每一根固定桩11在最低潮位线L以上的区域都设有混凝土保护装置111,保护每一根固定桩11不受到潮间带 的强腐蚀,从而大大延长固定桩11的使用寿命,也因此延长总成平台1的使用寿命,降低维修频率和成本。由于水起到隔绝空气中的氧的作用,固定桩11在水下的部分不易腐蚀,固定桩11位于水面以上的部分反而最容易腐坏。如果不设置混凝土保护装置,固定桩11在水上的部分一旦腐坏,将会导致固定桩11之间力的传递不再均衡,很可能造成整个总成平台1的失衡甚至倒塌。通过设置混凝土保护装置111,整个总成平台1的使用寿命能够长达50年。随着涨潮和落潮,水面P的高度会发生变化,因此混凝土保护装置111的最下端优选设置在最低潮位线L处。于实际应用中,混凝土保护装置111的最下端可以低于最低潮位线L。于具体应用中,在固定桩的11位于最低潮位线L以上的区域设有保护套,然后在保护套内灌注混凝土,从而形成混凝土保护装置111。
图5所示为根据本发明第二实施例提供的大型潮流能发电装置的局部俯视图。图6所示为根据本发明第二实施例提供的大型潮流能发电装置的局部侧视图。图7所示为根据本发明第二实施例提供的大型潮流能发电装置的单个内模块的俯视图。图8所示为根据本发明第二实施例提供的大型潮流能发电装置的安装示意图。请一并参考图5至图8。第二实施例的总成平台1、水平轴水轮发电机2、固定桩11、混凝土保护装置111、受力阻挡件12、受力支撑件13、支架14、安装空间15、栅栏导槽16、固定组件箱18、鼓风机181、通风管182、抽水泵183、排水管184、侧板19等与第一实施例中的相应元件的结构和功能基本相同,因此采用相同的标号。以下仅就不同之处予以说明。
于第二实施例中,大型潮流能发电装置包括总成平台1、至少一台水平轴水轮发电机2以及至少一个悬挂支撑柱31。至少一台水平轴水轮发电机2可分离地安装于总成平台1中。图5只绘出了大型潮流能发电装置最侧边的一个模块,因此只显示了一个总成平台1和一台水平轴水轮发电机2。在实际应用中,多个总成平台1和多台水平轴水轮发电机2可呈阵列排列,从而提高整个发电装置的发电功率。具体而言,另外一台水平轴水轮发电机2会安装于图5和图6中所示潮流能发电装置的右侧,因此有一个额外的受力阻挡件12设置于位于右侧中间的两个固定桩11上或设置于连接固定桩11的支架14上,且这个受力阻挡件12是位于外侧。相应地,位于右侧的固定桩11或支架14会额外地具有一个导槽121。
于本实施例中,潮流能发电装置还包括至少一个悬挂支撑柱31,悬挂支撑柱31的一端位于水面P上,另一端连通水平轴水轮发电机2或受力阻挡件12或受力支撑件13,使得人能够通过悬挂支撑柱31到达水面P以下进行维修或固 定操作。和第一实施例类似,本实施例的总成平台也包括至少两个固定组件箱18,每个固定组件箱18对应于受力阻挡件12设置且为中空。具体而言,本实施例中的潮流能发电装置包括三个悬挂支撑柱31。位于中间的悬挂支撑柱31的一端位于水面P上,另一端连通水平轴水轮发电机2。另外两个悬挂支撑柱31分别位于水平轴水轮发电机2沿水流方向D的两侧,并且这两个悬挂支撑柱31的另一端分别连通位于水平轴水轮发电机2两侧的固定组件箱18。两侧的悬挂支撑柱31可固定于导槽121内。换言之,于本实施例中,导槽121的作用不仅仅是引导固定组件箱18的滑动,便于固定组件箱18的安装固定。导槽121还起到固定和引导悬挂支撑柱31的作用。于其它实施例中,当没有固定组件箱18时,位于两侧的悬挂支撑柱31的另一端可直接连通受力支撑件13。
由于悬挂支撑柱31为密闭中空结构,可以在悬挂支撑柱31的内部设置爬梯。人员可通过中间的悬挂支撑柱31内部的爬梯进入水平轴水轮发电机2的内部进行工作(比如更换密封圈、更换机油等维修工作或者管道线路的布置工作)。当水平轴水轮发电机2发生故障时,可无需将水平轴水轮发电机2吊出水面,人员可以直接进入水平轴水轮发电机2的内部进行维修。人员也可通过两侧的悬挂支撑柱31到达固定组件箱18内完成固定组件箱18和受力阻挡件12之间的安装固定工作。
现有的潮流能发电装置大多数是在水平轴水轮发电机的下方设置单根承载桩,这样的安装方式有两个明显的缺点。第一个是上文已经提及的单根承载桩支撑将承受水流对水平轴水轮发电机全部的推力,从而导致弯矩和剪切力过大,所以无法承载更大单机规模的水平轴水轮发电机,使得发电成本居高不下。第二个是如果水平轴水轮发电机需要进行维修,那么需要人在水下拆除水平轴水轮发电机和承载桩之间的连接,然后将水平轴水轮发电机吊离海面,维修安全隐患大。并且,为了保证水平轴水轮发电机的正常运行,承载桩和水平轴水轮发电机之间的固定要非常牢靠,这也意味着解除二者之间的连接关系非常难,更不用提在水下进行操作,维修难度非常高。因此,现有的很多潮流能发电装置根本就不维修,一旦水平轴水轮发电机发生损害(比如密封圈由于长久使用发生松动而导致水平轴水轮发电机内部进水或者水平轴水轮发电机的机油要进行更换等),则整个发电装置直接进行报废。这也是造成现有的潮流能发电装置使用寿命短,成本高的重要原因之一,使得潮流能发电装置无法实现商业化。
然而,本实施例中的水平轴水轮发电机2,在需要进行维修时,维修人员可通过悬挂支撑柱31直接进入水平轴水轮发电机2的内部直接进行水下维修。于 实际应用中,本实施例的总成平台的使用寿命可以长达50年,但是水平轴水轮发电机的使用上限是20年,当水平轴水轮发电机2到达使用寿命时,只需解除水平轴水轮发电机2和总成平台1之间的固定连接,即可从下至上将水平轴水轮发电机2从水里吊出水面,更换新的水平轴水轮发电机2进行安装。本实施例的水平轴水轮发电机2通过倒挂式可分离的安装方式,水平轴水轮发电机2的维修更换成本和难度远远低于直接固定于海床上的水平轴水轮发电机的维修成本和难度。
本实施例的水平轴水轮发电机2在水下被悬挂支撑柱31和两侧的受力支撑件13进行固定,确保水平轴水轮发电机2在水流巨大的推力作用下不会发生晃动,产生的振动也在安全范围之内。因此,本实施例提供的潮流能发电装置可以运行更大规模的水平轴水轮发电机,这也意味着水平轴水轮发电机的单机装机功率会更大。现有的潮流能发电装置可以承受的最大单机装机功率为2MW,本实施例的潮流能发电装置可以直接承载和运行单机装机功率为5MW甚至10MW、20MW的水平轴水轮发电机。这极大地促进了海洋能发电产业的发展和推动技术的进步,给本行业带来根本性的变革。
同时,现有的潮流能发电装置即便采用2MW的单机装机功率,也因为没有解决维修等问题,无法持续发电。即便部分潮流能发电装置有考虑维修问题,但是因为维修成本高昂,导致潮流能产电的发电成本远高于其他能源发电的成本,因此现有的潮流能发电装置的商业价值一直很小。本实施例的悬挂支撑柱不仅起到支撑作用,还能够通人进到水平轴水轮发电机内部进行维修,大大降低了维修成本。
另外,本发明人之前申请的专利和实施例都需要制作一个完整的矩形框架来固定和安装水平轴水轮发电机,然而本实施例只需两个受力支撑件即可实现水平轴水轮发电机在水中的固定,大大减小了钢材的使用量,进一步降低了发电装置的成本。并且框架的设置不可避免地会阻挡水流,形成水流截面,降低水平轴水轮发电机对水流的利用率,本实施例的潮流能发电装置无需框架,就完全解决了这个问题。
于本实施例中,大型潮流能发电装置还包括至少一个连接件4,至少一个连接件4横向或纵向地连接悬挂支撑柱31水面以上的一端和总成平台1。当连接件横向连接时,连接件4也将三个悬挂支撑柱31位于水面以上的一端固定连接在一起。当需要将水平轴水轮发电机2和总成平台1相分离时,解除连接件4和总成平台1的连接关系即可。
于本实施例中,密闭中空的悬挂支撑柱31起到通人管道17的作用。于本实施例中,三个悬挂支撑柱31、两个固定组件箱18、两个受力支撑件13和水平轴水轮发电机2共同构成内模块。当固定组件箱损坏需要进行维修时,只需解除内模块与总成平台1之间的固定关系,然后将内模块从下往上吊出海面,即可进行内模块任何一处的维修或者更换操作。然而,本发明对此不作任何限定。于其它实施例中,两侧的通人管道17可直接设置在固定桩11内,虽然在这种情况下若需要进行维修时,总成平台的固定桩可能面临报废的风险,经济性较差。
和第一实施例类似,本实施例的大型潮流能发电装置中的每个悬挂支撑柱31(即通人管道17)对应地设置有鼓风机181、通风管182、抽水泵183以及排水管184,以保障水下工作人员的生命安全。鼓风机181、通风管182、抽水泵183以及排水管184的结构和功能与第一实施例相同,在此不再赘述。
如图9所示,于第三实施例中,悬挂支撑柱31的数量可为一个,位于中间的悬挂支撑柱31为密闭中空结构,位于两侧的悬挂支撑柱31可不中空或者不需要两侧的悬挂支撑柱31,人员从中间的悬挂支撑柱31进入到水平轴水轮发电机2的内部,然后通过中空的受力支撑件13的内部分别到达受力支撑件13的另一端,进行受力支撑件13与受力阻挡件12之间的固定或者进行固定组件箱18与受力阻挡件12之间的固定。如图10所示,于第四实施例中,悬挂支撑柱31的数量可为两个,位于两侧的悬挂支撑柱31为密闭中空结构,位于中间的悬挂支撑柱31可不中空或者不需要中间的悬挂支撑柱31,人员可通过悬挂支撑柱31和任意一侧的中空的受力支撑件13到达水平轴水轮发电机2的内部。如图11所示,于第五实施例中,悬挂支撑柱31的数量可为一个且位于左侧或者右侧,中间的悬挂支撑柱31和另一侧的悬挂支撑柱31可不中空或者不需要中间和另一侧的悬挂支撑柱31,人员通过最左侧的悬挂支撑柱31进入到受力支撑件13,然后通过中空的受力支撑件13内部到达水平轴水轮发电机2的内部,并且可穿过水平轴水轮发电机2和另一根受力支撑件13到达最右端。本发明对此不作任何限定。于其它实施例中,受力支撑件13也可不中空,其内部无需通人,人员可以分别通过三根中空的悬挂支撑柱31到达相应的地点。于这些实施例中,鼓风机181、通风管182、抽水泵183以及排水管184都可进行对应地设置。
图12所示为根据本发明第六实施例提供的大型潮流能发电装置的俯视图,图12中上边虚线圆圈为下边虚线圆圈标识处的放大。第六实施例的总成平台1、水平轴水轮发电机2、固定桩11、混凝土保护装置(图未示)、受力阻挡件12、 受力支撑件13、支架14、安装空间15、鼓风机(图未示)、通风管182、抽水泵(图未示)、排水管184、侧板19等与第一实施例中的相应元件的结构和功能基本相同,因此采用相同的标号。以下仅就不同之处予以说明。
于本实施例中,总成平台1不包括第一实施例中的固定组件箱,但是仍然有密封装置和固定组件(如固定螺栓或千斤顶)。受力支撑件13的一端是通过固定组件直接安装固定于受力阻挡件12上,密封装置对连接处进行密封。于本实施例中,四个通人管道17是沿固定桩11外进行设置,通人管道17的一端位于水面以上,另一端连通受力阻挡件12。人员可以通过通人管道17进入受力阻挡件12内,然后调节固定组件,从而进行受力支撑件13和受力阻挡件12的固定。于另一实施例中,可仅具有图12中位于最中间的通人管道17,这个通人管道17设置于支架14上,通过这一个通人管道,即可到达水下工作区域对位于四个地方的固定组件进行固定操作,这种设置方式成本最低。鼓风机、通风管182、抽水泵以及排水管184都可进行对应地设置,以保障人员的生命安全。
图13所示为根据本发明第七实施例提供的大型潮流能发电装置的俯视图。第七实施例的总成平台1、水平轴水轮发电机2、固定桩11、混凝土保护装置111、受力阻挡件12、受力支撑件13、支架14、安装空间15、栅栏导槽16、通人管道17、鼓风机、通风管、抽水泵、排水管、侧板19等与第一实施例中的相应元件的结构和功能基本相同,因此采用相同的标号。以下仅就不同之处予以说明。
于第七实施例中,潮流能发电装置不包括固定组件箱。总成平台还包括两组避震装置21,每组避震装置21设置于受力支撑件13与受力阻挡件12之间。每组避震装置21包括两个避震件,分别固定在受力支撑件13远离水平轴水轮发电机2的一端位于上下游的两侧。每个避震装置都抵靠于受力阻挡件12上。避震装置21可以采用特殊的聚乙烯高分子材料、橡胶材料或者弹簧等。通过设置避震装置21,可以有效地减小水平轴水轮发电机2可能产生的共振,
图14所示为根据本发明第八实施例提供的栅栏的示意图,图14中右边虚线圆圈为左边虚线圆圈标识处的俯视图。于本实施例中,总成平台包括至少两个栅栏3,分别设置于水平轴水轮发电机2的上下游两侧,每个栅栏3沿水流方向的宽度W大于或等于8厘米。现有的潮流能发电装置往往忽略了海洋中异物(比如海洋垃圾、海中浮冰等)对水轮发电机叶轮的损坏。发明人注意到了这点,因此采用设置栅栏的方式,从而降低海洋异物卷入叶轮中的概率。然而,经过一年多的实践发现,如果是通过钢丝编织形成的栅栏,经过水流持续不断 地冲击,钢丝交接处相互摩擦,位于交接处的钢丝的厚度将会不断变薄,最终钢丝断裂,从而丧失了栅栏拦截海洋异物的作用。更重要的是,断裂的钢丝会被绞入水轮发电机的叶轮中,破坏叶片,导致整个水平轴水轮发电机的损坏。这样不但没有起到保护叶轮的作用,还意外造成维修成本的攀升。因此,通过将栅栏3沿水流方向的宽度设置为大于或等于8厘米,无论水流如何冲击,栅栏将不会再次损坏。由于本领域的特殊性,潮流能水平轴水轮发电机每一次的维修或者每一次的更换元件,都会造成成本巨大的攀升,阻碍潮流能发电装置的商业化运用。本领域技术人员之前往往都陷入误区,一直从理论上去考量问题,而忽略了发电装置真正投入运用后的经济适用性。8厘米这个参数是本发明人经过不断地实践积累,总结经验教训,最后确定能够保证栅栏有足够长的使用寿命的参数。
于本实施例中,每个栅栏网格沿水深方向的高度仍然为钢丝的直径,即8mm左右。于实际应用中,栅栏3沿水流方向的宽度W可为30厘米,有效防止加拿大北部附近海域中冰凌的撞击,同时也确保钢丝不会被绞断。于本实施例中,栅栏垂直于水流方向且平行于水平面方向的长度根据对应安装的总成平台尺寸而定,本专利不做限定,比如可为15m*20m。栅栏沿水深方向的高度根据实施地水流环境的应力条件而定,本专利不做具体的限定。栅栏的网目可为方形或菱形结构,本专利对网目距离的大小不做限定,网目可为30cm*30cm。另外,本专利对栅栏支架和拦网的具体材料也不做限定。
图15所示为根据本发明第九实施例提供的大型潮流能发电装置的示意图。图16所示为根据本发明第九实施例提供的大型潮流能发电装置的安装示意图。如图15和图16所示,一种大型潮流能发电装置包括至少两个总成平台1和至少三个水平轴水轮发电机2。第九实施例中的总成平台1和水平轴水轮发电机2可以和第二实施例中披露的总成平台和水平轴水轮发电机的结构一样,在此相同结构采用相同标号进行表示。第九实施例中的潮流能发电装置也具有第一实施例或第二实施例中提到的所有其它部件,在此不再赘述。
于第九实施例中,大型潮流能发电装置包括至少四根固定桩11,至少四根固定桩11通过支架14连成一体且围绕形成一个安装空间15,每根固定桩11的一端打桩固定于海床F,另一端延伸到水面以上,至少四根固定桩11沿着水流方向分左右两列布放,其中每一列至少两根固定桩11沿着水流方向依次布放。每个总成平台1的安装空间15内安装有至少一个水平轴水轮发电机2。至少两个总成平台1沿着水流方向左右布放,两个总成平台1之间的间隔G和一个水 平轴水轮发电机2的叶轮直径相匹配,使得额外的至少一个水平轴水轮发电机2能够安装于两个总成平台1之间。间隔G的方向是平行于水平面且垂直于水流方向的方向。具体而言,间隔G的长度大于一个水平轴水轮发电机2的叶轮直径从而使得两个总成平台1之间能够装下一个水平轴水轮发电机2。每个总成平台1沿平行于水平面的方向装有一个水平轴水轮发电机2,沿水深方向(即垂直于水平面的方向)可安装有一个或一个以上的水平轴水轮发电机2。同样地,两个总成平台之间沿平行于水平面的方向装有一个水平轴水轮发电机2,沿水深方向(即垂直于水平面的方向)可安装有一个或一个以上的水平轴水轮发电机2。
本发明人之前申请的专利和具体的实施案例中应用的潮流能发电装置,先在岸上将一个水平轴水轮发电机安装在一个内框架内形成一个内模块,接着外框架打桩固定于海床上形成总成平台,然后将内模块吊入位于水中的外框架,从而完成潮流能发电装置的安装。就制造成本而言,潮流能发电装置的总的制造成本包括总成平台的制造成本、外框架和内框架的制造成本以及水平轴水轮发电机本身的制造成本。本实施例以及前面提到的任意实施例的潮流能发电装置,都摒弃了传统框架的使用,大大减少了在制造过程中需要的钢材量,从而大幅度降低了制造成本。
其次,就安装成本而言,现有的潮流能发电装置的安装成本包括总成平台的安装成本和内模块的安装成本。如果内模块包括了框架,则内模块的安装成本将包括发电机本身的安装成本和对应框架的安装成本。如果要在垂直于水流方向且平行于水平面的方向上安装三台水轮发电机,则需要三个框架的安装成本加上三台水轮发电机的安装成本再加上三个总成平台的安装成本。然而,本实施例的安装方式,在无需安装框架之外,直接减少了一个平台,即只需要两个安装平台,即可安装三台水轮发电机,这样使得潮流能发电装置的安装成本急剧减少。如果需要布放五台水轮发电机,则只需要三个总成平台。
对于潮流能发电装置的实际成本而言,总成平台和水轮发电机的成本可能占到各一半,大部分情况下,总成平台的成本甚至会高于水轮发电机的成本。本实施例揭露的安装方式,使得潮流能发电装置在垂直于水流方向且平行于水平面方向的“延展”成本得到大幅度降低,实现更低成本的阵列化排列,真正将潮流能发电装置做到大型化。
于实际安装过程中,如果安装固定桩太近的话,容易导致海床的岩土松散,所以需要间隔桩径的3-5倍以上的距离才能固定另一根桩。这样导致现有的潮流能发电装置对水流的利用率低,浪费了资源。举例而言,如果固定桩的直径为 3m,则需要在9m开外的地方打另外一根固定桩。否则相邻的总成平台将固定不牢,并且在运行过程中,可能会导致桩的塌陷歪斜,整个装置报废要重新安装。本实施例的安装方式完全避免了现有技术中的这个问题,并且在降低成本的同时实现潮流能的充分利用。
图17所示为根据本发明第十实施例提供的大型潮流能发电装置的示意图。如图17所示,于第十实施例中,每个总成平台内1可以沿水深方向安装至少两台水平轴水轮发电机2。本发明对此不作任何限定,于实际应用中,可根据不同的水深高度,在不同的安装空间内,有的安装一台有的安装多台水平轴水轮发电机。
本申请提及的所有实施例中的所有特征可以依据实际情况进行自由组合使用。举例而言,第八实施例中的栅栏可以运用到第一、二、三、四、五、六、七、九、十任一实施例的潮流能发电装置中,第八实施例中的栅栏也可以用于任何现有的潮流能发电装置中。第一、二、三、四、五、六、七、九、十任一实施例的潮流能发电装置也可以采用其他结构的栅栏。多个第一、二、三、四、五、六、七、十实施例披露的潮流能发电装置可以按照第九实施例中披露的方法进行安装。第一、二、三、四、五、六、七、十实施例披露的大型潮流能发电装置也可以按照现有的其它布放方式进行阵列化排列。第九实施例的安装方式也可以适用于现有的其它结构的潮流能发电装置。第九实施例中的每个总成平台和内模块的结构可以完全和第一、二、三、四、五、六、七、十实施例相同,也可以不相同。第一至第九实施例,都可以如第十实施例所述的,在水深方向上安装至少两台水平轴水轮发电机。第十实施例的潮流能发电装置的每个总成平台和内模块的结构可以完全和第一、二、三、四、五、六、七实施例相同。
综上所述,本发明通过将四根固定桩和支架连在一起形成安装空间,然后水平轴水轮发电机固定于安装空间内,而不是像现有技术一样将水平轴水轮发电机安装于框架内,大幅度降低了钢材的使用,降低了制造和安装成本。并且,本发明通过设置位于水平轴水轮发电机两侧的受力支撑件和受力阻挡件,能够将水平轴水轮发电机受到的水流的推力均衡地传递到两侧,从而分散给整个总成平台,使得整个总成平台能够承载更大功率的单个水平轴水轮发电机,大幅度降低了潮流能发电装置的发电成本。特别地,本发明的水平轴水轮发电机在水中具有“固定点”,因此避免了现有技术中水平轴水轮发电机在水流巨大的推力作用下,因为晃动产生共振现象从而容易损坏的问题。通过采用本申请提供 的大型潮流能发电装置及其总成平台,能够真正使得潮流能发电装置实现大型化,将潮流能发电的成本降低到低于火力发电的成本,从而真正实现潮流能发电的商业推广和运用。
虽然本发明已由较佳实施例揭露如上,然而并非用以限定本发明,任何熟知此技艺者,在不脱离本发明的精神和范围内,可作些许的更动与润饰,因此本发明的保护范围当视权利要求书所要求保护的范围为准。

Claims (10)

  1. 一种大型潮流能发电装置的总成平台,其内安装有至少一台水平轴水轮发电机,其特征在于,所述大型潮流能发电装置的总成平台包括:
    支架;
    至少四根固定桩,所述至少四根固定桩通过支架连成一体且围绕形成一个安装空间,至少一个水平轴水轮发电机安装于安装空间内,每根固定桩的一端打桩固定于海床,另一端延伸到水面以上,所述至少四根固定桩沿着水流方向分左右两列布放,其中每一列至少两根固定桩沿着水流方向依次布放;
    至少两个受力阻挡件,分别固定于对应的固定桩或支架上且位于水面以下水平轴水轮发电机沿水流方向的左右两侧;
    至少两个受力支撑件,所述至少两个受力支撑件的一端分别安装在所述水平轴水轮发电机沿水流方向的左右两侧,另一端分别抵靠在对应的受力阻挡件上,以抵挡水流对所述水平轴水轮发电机的冲击力。
  2. 根据权利要求1所述的大型潮流能发电装置的总成平台,其特征在于,所述总成平台还包括至少两组避震装置,每组避震装置设置于受力支撑件与受力阻挡件之间。
  3. 根据权利要求1所述的大型潮流能发电装置的总成平台,其特征在于,所述总成平台还包括至少一个通人管道,所述至少一个通人管道的一端位于水面以上,另一端连通所述水平轴水轮发电机或其中一个受力支撑件或受力阻挡件,使得人能够通过所述至少一个通人管道到达水面以下进行维修或固定操作。
  4. 根据权利要求3所述的大型潮流能发电装置的总成平台,其特征在于,所述总成平台还包括至少一个鼓风机和一个通风管,所述通风管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,通风管从水面以上通到水面以下以使水面下的工作区内能够进行换风。
  5. 根据权利要求3所述的大型潮流能发电装置的总成平台,其特征在于,所述总成平台还包括至少一个抽水泵和至少一根排水管,排水管可固定或可拆卸地沿通人管道内或沿通人管道外进行布置,排水管从水面以上通到水面以下,抽水泵抽取水面以下的工作区内的积水并通过排水管排出到水面以上。
  6. 根据权利要求1所述的大型潮流能发电装置的总成平台,其特征在于,总成平台还包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构。
  7. 根据权利1所述的大型潮流能发电装置的总成平台,其特征在于,总成平台的每一根固定桩在最低潮位线以上的区域都设有混凝土保护装置。
  8. 一种大型潮流能发电装置,其特征在于,包括:
    如权利要求1-7中任一项所述的总成平台;
    至少一个水平轴水轮发电机,可分离地安装于所述总成平台中;
    至少一个悬挂支撑柱,为密闭中空结构,所述悬挂支撑柱的一端位于水面以上,所述悬挂支撑柱的另一端连通所述水平轴水轮发电机或受力阻挡件或受力支撑件,使得人能够通过悬挂支撑柱到达水面以下进行维修或固定操作。
  9. 根据权利要求8所述的大型潮流能发电装置,其特征在于,总成平台包括至少两个固定组件箱,每个固定组件箱对应于受力阻挡件设置且为中空结构,悬挂支撑柱的数量为至少两个,所述至少两个悬挂支撑柱的所述另一端分别连通对应的固定组件箱。
  10. 根据权利要求8所述的大型潮流能发电装置,其特征在于,悬挂支撑柱的数量为三个,两个悬挂支撑柱的所述另一端分别连通位于水平轴水轮发电机两侧的受力阻挡件或受力支撑件,另一个悬挂支撑柱的所述另一端连通所述水平轴水轮发电机。
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