CN110985984A - Tidal energy ocean guide lighthouse - Google Patents

Abstract

The invention discloses a tidal energy ocean guiding lighthouse which comprises a tower body, a supporting body and a storage platform, wherein the tower body is fixedly arranged on the top surface of the supporting body, the supporting body is fixedly arranged on the sea bottom, the storage platform is fixedly arranged on the right side surface of the supporting body, two power cavities with leftward openings and symmetrical front and back are arranged in the supporting body, turbine blades capable of rotating when being impacted by seawater are arranged in the power cavities, a storage cavity with an upward opening and capable of storing seawater is arranged in the storage platform, and when seawater rises and falls is arranged on the front side of the power cavity, the tidal energy ocean guiding lighthouse can drive a turbine to rotate to generate electric energy through seawater impact of rising tide.

Description

Tidal energy ocean guide lighthouse

Technical Field

The invention relates to the technical field of new energy, in particular to a tidal energy ocean guidance lighthouse.

Background

At present, with the development of society, earth resources are continuously developed, the traditional way of generating electric energy not only consumes resources seriously, but also pollutes the environment, and while science and technology progress, more and more new energy is developed, ocean tidal energy is used as clean energy, and has been used on infrastructure buildings or equipment built in various ocean areas, and a guide lighthouse is used as a target light source for guiding the ship advancing direction near the ocean coast, and a large amount of electric energy is needed for lighting at night, and the rotation of a lighting lamp at the top of the tower consumes resources very much.

Disclosure of Invention

It is an object of the present invention to provide a tidal energy ocean guidance lighthouse that overcomes the above-mentioned deficiencies of the prior art.

According to the embodiment of the invention, the tidal energy ocean guiding lighthouse comprises a tower body, a supporting body and a storage platform, wherein the tower body is fixedly arranged on the top surface of the supporting body, the supporting body is fixedly arranged on the sea bottom, the storage platform is fixedly arranged on the right side surface of the supporting body, two power cavities with leftward openings and symmetrical front and back are arranged in the supporting body, turbine blades capable of rotating under the impact of seawater are arranged in the power cavities, a storage cavity with an upward opening and capable of storing seawater is arranged in the storage platform, a one-way mechanism capable of introducing seawater into the storage cavity to be stored and enabling the turbine blades on the front side to rotate is arranged in the power cavity on the front side, a control mechanism capable of discharging the seawater in the storage cavity and driving the turbine blades on the rear side to rotate is arranged in the power cavity on the rear side when the seawater is ebb tide, and a power generation cavity is arranged in the tower body, the power generation mechanism is characterized in that a magnet and a magnetic induction coil are arranged in the power generation cavity, the magnet is located on the periphery of the magnetic induction coil, a power generation mechanism capable of driving the magnet to rotate through rotation of the turbine blades and enabling the magnetic induction coil to output electricity is arranged in the power generation cavity, an annular cavity with an outward opening is arranged in the tower body, a rotating ring is arranged on the inner wall of the annular cavity in a sliding mode, a support frame is fixedly arranged on the periphery of the rotating ring, an illuminating lamp is fixedly arranged on the other side face of the support frame, a rotating cavity is communicated with the lower side of the annular cavity, and a power mechanism capable of controlling the rotating ring to drive.

Further technical scheme, one-way mechanism includes the closed piece, is located the front side the right side intercommunication in power chamber is equipped with logical chamber and spring chamber, lead to the chamber with spring chamber intercommunication, the downside intercommunication that leads to the chamber is equipped with the U die cavity, the U die cavity include two with the opening that leads to the chamber intercommunication, lead to the chamber with store the chamber intercommunication, the horizontal slip is equipped with the closed piece on the roof in spring chamber, the closed piece can seal lead to the chamber with store the chamber, the right flank of closed piece with fixed mounting has the spring between the right wall in spring chamber.

In a further technical scheme, the control mechanism comprises a floating block and a moving block, a control cavity and a placing cavity are communicated and arranged at the lower side of the power cavity at the rear side, the floating block is placed in the placing cavity, a reel is rotatably arranged on the rear wall of the control cavity, a connecting rope is wound on the periphery of an inner ring of the reel, the connecting rope extending part penetrates through the supporting body and is fixedly connected with the floating block, teeth are arranged on the outer circumference of the outer ring of the reel, a torsion spring is fixedly arranged between the front side surface of the reel and the front wall of the control cavity, sliding plates are arranged on the bottom wall of the control cavity in a left-right sliding manner, the top surface of the sliding plate is provided with teeth, the sliding plate is meshed with the reel, a moving block is arranged on the right wall of the control cavity in an up-and-down sliding manner, a connecting rod is hinged between the moving block and the sliding plate, and the moving block can be positioned at the rear side in a closed mode and used for the power cavity and the storage cavity.

According to the technical scheme, a fixing block is fixedly arranged on the top wall of the power cavity, a gear cavity is formed in the fixing block, a vertical shaft is arranged on the top wall of the gear cavity in a rotating mode, a first bevel gear is fixedly arranged on the bottom surface of the vertical shaft and located on the front side of the left wall of the gear cavity and located on the rear side of the left wall of the gear cavity, a cross shaft is arranged on the right wall of the gear cavity in a rotating mode, a second bevel gear is fixedly arranged on the periphery of the cross shaft in the gear cavity and meshed with the first bevel gear, the extending portion of the cross shaft extends into the power cavity, a turbine blade is fixedly arranged on the periphery of the cross shaft, and a filter screen is fixedly arranged between the upper wall and the lower wall.

A further technical scheme, electricity generation mechanism establishes including rotating the transmission shaft on the electricity generation chamber diapire, magnet sets firmly on the periphery of transmission shaft, the dead lever has set firmly on the roof in electricity generation chamber, magnetism inductance coil sets firmly on the bottom surface of dead lever, the transmission chamber has been seted up to the downside in electricity generation chamber, two the upwards extension portion of vertical axis runs through the fixed block, the supporter with the inner wall of tower body to stretch into in the transmission chamber, and its top surface sets firmly first worm wheel, it is equipped with first worm all to rotate on the wall around the transmission chamber, first worm with first worm wheel meshing, the ratchet group has all set firmly on the another side of first worm, all rotate on the inner wall in transmission chamber and be equipped with two bilateral symmetry's second worm, the another side of second worm with ratchet group power is connected, the transmission shaft downwardly extending part penetrates through the inner wall of the tower body and extends into the transmission cavity, a second worm wheel is fixedly arranged on the periphery of the transmission shaft downwardly extending part, and the second worm wheel is meshed with the two second worms.

A further technical scheme, power unit establishes including rotating the rotation axis on the rotatory chamber diapire, the top surface of rotation axis has set firmly the revolving stage, the revolving stage with rotatory ring fixed connection, the rotatory intra-annular that has the opening decurrent annular conducting layer, annular conducting layer with light electric connection, the motor chamber has been seted up to the downside in rotatory chamber, the motor has set firmly on the right wall in motor chamber, the left side power connection of motor is equipped with the motor shaft, the third bevel gear has set firmly on the left surface of motor shaft, rotation axis downwardly extending part stretches into the motor intracavity, and its bottom surface has set firmly the fourth bevel gear, the fourth bevel gear with the meshing of third bevel gear.

According to a further technical scheme, a conducting layer is fixedly embedded in the tower body and communicated with the magnetic induction coil, the motor and the annular conducting layer.

The invention has the beneficial effects that: the invention can drive the turbine to rotate to generate electric energy through seawater impact of rising tide, can effectively reduce energy consumption through tide clean energy, improve effective utilization of resources, and can drive the turbine on the other side through reverse impact of stored seawater when the seawater is ebbed, so that the lighting time of the lighthouse is longer, wherein the one-way mechanism can unidirectionally introduce and store the seawater impacted by rising tide into the storage cavity, the control mechanism can discharge the seawater in the storage cavity when the seawater is ebbed, the power generation mechanism can generate electric energy through the mode that the seawater impacts the turbine to rotate, and the power mechanism can rotate for lighting.

Drawings

FIG. 1 is a schematic view of the overall internal structure of the present invention;

FIG. 2 is a schematic view of the internal structure of a control chamber and a power chamber located at the rear side in the present invention;

FIG. 3 is a top view of the internal structure of the transmission chamber of the present invention;

fig. 4 is an enlarged schematic view of the invention at a in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 4, a tidal energy ocean guiding lighthouse according to an embodiment of the present invention comprises a tower body 11, a supporting body 37 and a storage platform 52, wherein the tower body 11 is fixed on the top surface of the supporting body 37, the supporting body 37 is fixed on the sea bottom, the storage platform 52 is fixed on the right side surface of the supporting body 37, two power chambers 39 with left openings and symmetrical front and back are arranged in the supporting body 37, turbine blades 40 capable of rotating when being impacted by seawater are arranged in each power chamber 39, a storage chamber 51 with an upward opening and capable of storing seawater is arranged in the storage platform 52, a one-way mechanism 101 capable of introducing seawater into the storage chamber 51 to store seawater and rotating the turbine blades 40 on the front side when the seawater is in the power chamber on the front side, a control mechanism 102 capable of discharging seawater from the storage chamber 51 and driving the turbine blades 40 on the rear side to rotate when the seawater is in the power chamber on the rear side 39, the power generation device is characterized in that a power generation cavity 29 is formed in the tower body 11, a magnet 28 and a magnetic induction coil 27 are arranged in the power generation cavity 29, the magnet 28 is located on the periphery of the magnetic induction coil 27, a power generation mechanism 103 which can drive the magnet 28 to rotate through the rotation of the turbine blades 40 and enable the magnetic induction coil 27 to output power is arranged in the power generation cavity 29, an annular cavity 15 with an outward opening is arranged in the tower body 11, a rotating ring 14 is arranged on the inner wall of the annular cavity 15 in a sliding mode, a support frame 13 is fixedly arranged on the periphery of the rotating ring 14, an illuminating lamp 12 is fixedly arranged on the other side face of the support frame 13, a rotating cavity 18 is communicated with the lower side of the annular cavity 15, and a power mechanism 104 which can control the rotating ring 14 to.

In addition, in one embodiment, the one-way mechanism 101 includes a closed block 47, a through cavity 46 and a spring cavity 49 are provided on the right side of the power cavity 39 on the front side in communication, the through cavity 46 is communicated with the spring cavity 49, a U-shaped cavity 48 is provided on the lower side of the through cavity 46 in communication, the U-shaped cavity 48 includes two openings communicated with the through cavity 46, the through cavity 46 is communicated with the storage cavity 51, a closed block 47 is provided on the top wall of the spring cavity 49 in a sliding manner, the closed block 47 can close the through cavity 46 and the storage cavity 51, a spring 50 is fixedly installed between the right side surface of the closed block 47 and the right wall of the spring cavity 49, when seawater flood tide rushes into the power cavity 39 on the front side, the seawater can push the closed block 47 to move to the right, and further the through cavity 46 can be communicated with the storage cavity 51, and further the seawater can enter the storage cavity 51, at the same time, the turbine blades 40 can be driven to rotate, when the seawater is ebb, the closing block 47 moves leftwards, the through cavity 46 can be closed, and then the seawater in the storage cavity 51 can not flow out of the power cavity 39 on the front side.

In addition, in one embodiment, the control mechanism 102 includes a float block 53 and a moving block 59, a control chamber 56 and a placing chamber 55 are provided at the rear side of the lower side of the power chamber 39 in communication, the float block 53 is placed in the placing chamber 55, a reel 62 is rotatably provided on the rear wall of the control chamber 56, a connecting rope 54 is wound on the outer circumference of the inner ring of the reel 62, the extending portion of the connecting rope 54 penetrates through the support body 37 and is fixedly connected with the float block 53, teeth are provided on the outer circumference of the outer ring of the reel 62, a torsion spring 63 is fixedly provided between the front side surface of the reel 62 and the front wall of the control chamber 56, a sliding plate 57 is provided on the bottom wall of the control chamber 56 in a left-right sliding manner, teeth are provided on the top surface of the sliding plate 57, the sliding plate 57 is engaged with the reel 62, the moving block 59 is provided on the right wall of the, a connecting rod 58 is hinged between the moving block 59 and the sliding plate 57, the moving block 59 can close the power cavity 39 and the storage cavity 51 which are positioned at the rear side, when seawater rises and rushes into the power cavity 39 which is positioned at the rear side, the floating block 53 floats, so that the reel 62 can drive the sliding plate 57 to move rightwards, the connecting rod 58 can drive the moving block 59 to ascend, then the moving block 59 can close the power cavity 39 and the storage cavity 51 which are positioned at the rear side, when seawater falls, the floating block 53 descends into the placing cavity 55, at the moment, the reel 62 can be reversely rotated through the torsion spring 63, the reel 62 can withdraw the connecting rope 54, the sliding plate 57 is controlled to move leftwards, then the connecting rod 58 can drive the moving block 59 to descend, so that the seawater in the storage cavity 51 can rush into the power cavity 39 which is positioned at the rear side, the transverse shaft 41 in the power chamber 39 on the rear side can be rotated.

In addition, in one embodiment, a fixed block 42 is fixedly arranged on the top wall of the power cavity 39, a gear cavity 45 is formed in the fixed block 42, a vertical shaft 36 is rotatably arranged on the top wall of the gear cavity 45, a first bevel gear 44 is fixedly arranged on the bottom surface of the vertical shaft 36, a horizontal shaft 41 is rotatably arranged on both the left wall of the gear cavity 45 at the front side and the right wall of the gear cavity 45 at the rear side, a second bevel gear 43 is fixedly arranged on the periphery of the horizontal shaft 41 in the gear cavity 45, the second bevel gear 43 is engaged with the first bevel gear 44, the extending part of the horizontal shaft 41 extends into the power cavity 39, the turbine blades 40 are fixedly arranged on the periphery of the horizontal shaft 41, a filter screen 38 is fixedly arranged between the upper and lower walls of the power cavity 39, seaweed or garbage can be prevented from entering the power cavity 39 through the filter screen 38 and being impacted by seawater through the turbine blades 40, the transverse shaft 41 is rotated and in turn the vertical shaft 36 is rotated.

In addition, in one embodiment, the power generation mechanism 103 includes a transmission shaft 30 rotatably disposed on the bottom wall of the power generation cavity 29, the magnet 28 is fixedly disposed on the periphery of the transmission shaft 30, the top wall of the power generation cavity 29 is fixedly provided with the fixing rod 26, the magnetic induction coil 27 is fixedly disposed on the bottom surface of the fixing rod 26, the lower side of the power generation cavity 29 is provided with a transmission cavity 31, the upward extending portions of the two vertical shafts 36 penetrate through the fixing block 42, the supporting body 37 and the inner wall of the tower body 11 and extend into the transmission cavity 31, the top surface of the transmission cavity is fixedly provided with a first worm wheel 35, the front wall and the rear wall of the transmission cavity 31 are respectively rotatably provided with a first worm 33, the first worm wheel 33 is engaged with the first worm wheel 35, the other side surface of the first worm wheel 33 is respectively and fixedly provided with a ratchet group 32, the inner wall of the transmission cavity 31 is respectively and rotatably provided with two second worm wheels 61 which are bilateral, the another side of second worm 61 with ratchet group 32 power connection, the downwardly extending part of transmission shaft 30 runs through the inner wall of tower body 11, and stretch into in the transmission chamber 31, and set firmly second worm wheel 60 in its periphery, second worm wheel 60 and two second worm 61 all meshes, through vertical shaft 36's rotation can make first worm 33 drives second worm 61 rotates, then can make transmission shaft 30 rotates, then can make magnet 28 is in the rotation of magnetic induction coil 27 periphery, and then can make magnetic induction coil 27 produces electricity, through ratchet group 32 can make one side vertical shaft 36 rotates and can not influence the opposite side vertical shaft 36 rotates.

In addition, in one embodiment, the power mechanism 104 includes a rotating shaft 20 rotatably disposed on the bottom wall of the rotating cavity 18, a rotating table 19 is fixedly disposed on the top surface of the rotating shaft 20, the rotating table 19 is fixedly connected to the rotating ring 14, an annular conductive layer 16 with a downward opening is fixedly embedded in the rotating ring 14, the annular conductive layer 16 is electrically connected to the illuminating lamp 12, a motor cavity 22 is disposed on the lower side of the rotating cavity 18, a motor 25 is fixedly disposed on the right wall of the motor cavity 22, a motor shaft 24 is dynamically connected to the left side of the motor 25, a third bevel gear 23 is fixedly disposed on the left side of the motor shaft 24, a downward extending portion of the rotating shaft 20 extends into the motor cavity 22, and a fourth bevel gear 21 is fixedly disposed on the bottom surface of the rotating shaft, the fourth bevel gear 21 is engaged with the third bevel gear 23, and by the operation of the motor 25, the motor shaft 24 can drive the rotating shaft 20 to rotate, so that the rotating ring 14 can be driven by the rotating platform 19 to rotate, the illuminating lamp 12 can be driven by the supporting frame 13 to rotate, and the illuminating lamp 12 can emit light through the annular conductive layer 16 for illumination.

In addition, in an embodiment, a conductive layer 17 is fixedly embedded in the tower body 11, the conductive layer 17 is communicated with the magnetic induction coil 27, the motor 25 and the annular conductive layer 16, and the motor 25 can be operated by enabling the electricity generated by the magnetic induction coil 27 to be conducted into the motor 25 and the annular conductive layer 16 through the conductive layer 17.

In the initial state, the closing block 47 is positioned at the leftmost side, the closing block 47 closes the through cavity 46 and the storage cavity 51, the floating block 53 is positioned in the placing cavity 55, and the moving block 59 is in the open state.

When the seawater tide rushes into the power cavity 39, the seawater can push the sealing block 47 to move rightwards, so that the through cavity 46 is communicated with the storage cavity 51, the seawater can enter the storage cavity 51 and simultaneously drive the turbine blades 40 to rotate, when the seawater tide falls, the sealing block 47 moves leftwards, so that the through cavity 46 can be sealed, so that the seawater in the storage cavity 51 can not flow out from the power cavity 39, the floating block 53 floats when the seawater tide rushes into the power cavity 39, so that the reel 62 drives the sliding plate 57 to move rightwards, the connecting rod 58 can drive the moving block 59 to ascend, so that the moving block 59 can be sealed in the power cavity 39 and the storage cavity 51, when the seawater tide falls into the placing cavity 55, at the moment, the torsion spring 63 can make the reel 62 rotate backwards, so that the reel 62 can withdraw the connecting rope 54, the sliding plate 57 is controlled to move leftwards, then the connecting rod 58 drives the moving block 59 to descend, so that seawater in the storage cavity 51 can be flushed into the power cavity 39 on the rear side, then the transverse shaft 41 in the power cavity 39 on the rear side can be driven to rotate, seaweed or garbage can be prevented from entering the power cavity 39 through the filter screen 38, the transverse shaft 41 can be driven to rotate through the impact of the seawater through the turbine blades 40, then the vertical shaft 36 can be driven to rotate, the first worm 33 can drive the second worm 61 to rotate through the rotation of the vertical shaft 36, then the transmission shaft 30 can be driven to rotate, the magnet 28 can rotate on the periphery of the magnetic induction coil 27, further the magnetic induction coil 27 can generate electricity, the vertical shaft 36 on one side can be driven to rotate through the ratchet set 32 without influencing the vertical shaft 36 on the other side to rotate, the electricity generated by the magnetic induction coil 27 can be conducted into the motor 25 and the annular conductive layer 16 through the conductive layer 17, and then the motor 25 can be driven to, by the operation of the motor 25, the motor shaft 24 can drive the rotation shaft 20 to rotate, so that the rotation ring 14 can be driven by the rotation platform 19 to rotate, and the illumination lamp 12 can be driven by the support frame 13 to rotate, and the illumination lamp 12 can emit light through the annular conductive layer 16 for illumination.

The invention has the beneficial effects that: the invention can drive the turbine to rotate to generate electric energy through seawater impact of rising tide, can effectively reduce energy consumption through tide clean energy, improve effective utilization of resources, and can drive the turbine on the other side through reverse impact of stored seawater when the seawater is ebbed, so that the lighting time of the lighthouse is longer, wherein the one-way mechanism can unidirectionally introduce and store the seawater impacted by rising tide into the storage cavity, the control mechanism can discharge the seawater in the storage cavity when the seawater is ebbed, the power generation mechanism can generate electric energy through the mode that the seawater impacts the turbine to rotate, and the power mechanism can rotate for lighting.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (7)

1. The utility model provides a beacon is guided to tidal energy ocean, includes tower body, supporter and storage platform, its characterized in that: the seawater desalination tower comprises a tower body, a supporting body, a storage table, a one-way mechanism and a control mechanism, wherein the tower body is fixedly arranged on the top surface of the supporting body, the supporting body is fixedly arranged on the seabed, the storage table is fixedly arranged on the right side surface of the supporting body, two power cavities with leftward openings and symmetrical front and back are arranged in the supporting body, turbine blades capable of rotating when being impacted by seawater are arranged in the power cavities, a storage cavity with an upward opening and capable of storing seawater is arranged in the storage table, the power cavity on the front side is internally provided with the one-way mechanism capable of introducing seawater into the storage cavity to store seawater and enabling the turbine blades on the front side to rotate when the seawater is tidal high, and the power cavity on the rear side is internally provided with the control mechanism capable of discharging the;

the power generation device is characterized in that a power generation cavity is formed in the tower body, a magnet and a magnetic induction coil are arranged in the power generation cavity, the magnet is located on the periphery of the magnetic induction coil, a power generation mechanism capable of driving the magnet to rotate through rotation of the turbine blades and enabling the magnetic induction coil to output electricity is arranged in the power generation cavity, a ring cavity with an outward opening is arranged in the tower body, a rotating ring is arranged on the inner wall of the ring cavity in a sliding mode, a support frame is fixedly arranged on the periphery of the rotating ring, an illuminating lamp is fixedly arranged on the other side face of the support frame, a rotating cavity is communicated with the lower side of the ring cavity, and a power mechanism capable of controlling the rotating.

2. The tidal energy ocean guidance lighthouse of claim 1, wherein: one-way mechanism includes the closing piece, is located the front side the right side intercommunication in power chamber is equipped with logical chamber and spring chamber, lead to the chamber with spring chamber intercommunication, the downside intercommunication that leads to the chamber is equipped with the U die cavity, the U die cavity include two with the opening that leads to the chamber intercommunication, lead to the chamber with store the chamber intercommunication, it is equipped with the closing piece to slide from side to side on the roof in spring chamber, the closing piece can seal lead to the chamber with store the chamber, the right flank of closing piece with fixed mounting has the spring between the right wall in spring chamber.

3. The tidal energy ocean guidance lighthouse of claim 1, wherein: the control mechanism comprises a floating block and a moving block, a control cavity and a placing cavity are communicated and arranged at the lower side of the power cavity at the rear side, the floating block is placed in the placing cavity, a reel is rotatably arranged on the rear wall of the control cavity, a connecting rope is wound on the periphery of an inner ring of the reel, the connecting rope extending part penetrates through the supporting body and is fixedly connected with the floating block, teeth are arranged on the outer circumference of the outer ring of the reel, a torsion spring is fixedly arranged between the front side surface of the reel and the front wall of the control cavity, sliding plates are arranged on the bottom wall of the control cavity in a left-right sliding manner, the top surface of the sliding plate is provided with teeth, the sliding plate is meshed with the reel, a moving block is arranged on the right wall of the control cavity in an up-and-down sliding manner, a connecting rod is hinged between the moving block and the sliding plate, and the moving block can be positioned at the rear side in a closed mode and used for the power cavity and the storage cavity.

4. The tidal energy ocean guidance lighthouse of claim 1, wherein: the utility model discloses a power cavity, including power chamber, gear chamber, fixed block, gear chamber, horizontal axis, first bevel gear, second bevel gear, power chamber, rear side, power chamber, turbine leaf, the filter screen has set firmly on the roof in power chamber, the gear chamber has seted up in the fixed block, it is equipped with vertical axis to rotate on the roof in gear chamber, the bottom surface of vertical axis sets firmly first bevel gear, is located the front side on the left wall in gear chamber with be located the rear side all rotate on the right wall in gear chamber and be equipped with the cross axle, be located the gear chamber the cross axle periphery has set firmly second bevel gear, second bevel gear with first bevel gear meshing, the cross axle extension stretches.

5. The tidal energy ocean guidance lighthouse of claim 4, wherein: the power generation mechanism comprises a transmission shaft which is rotatably arranged on the bottom wall of the power generation cavity, the magnet is fixedly arranged on the periphery of the transmission shaft, a fixed rod is fixedly arranged on the top wall of the power generation cavity, a magnetic induction coil is fixedly arranged on the bottom surface of the fixed rod, a transmission cavity is arranged at the lower side of the power generation cavity, two upward extending parts of the vertical shaft penetrate through the fixed block, the supporting body and the inner wall of the tower body and extend into the transmission cavity, a first worm wheel is fixedly arranged on the top surface of the power generation cavity, a first worm is rotatably arranged on the front wall and the rear wall of the transmission cavity, the first worm is meshed with the first worm wheel, a ratchet group is fixedly arranged on the other side surface of the first worm, a second worm which is provided with two bilateral symmetry is rotatably arranged on the inner wall of the transmission cavity, the other side surface of the second worm is connected with the power of the ratchet group, and the downward extending part of the transmission, and the worm wheel extends into the transmission cavity, a second worm wheel is fixedly arranged on the periphery of the worm wheel, and the second worm wheel is meshed with the two second worms.

6. The tidal energy ocean guidance lighthouse of claim 1, wherein: power unit establishes including rotating the rotation axis on the rotatory chamber diapire, the top surface of rotation axis has set firmly the revolving stage, the revolving stage with rotatory ring fixed connection, the annular conducting layer that the opening is decurrent is inlayed to the revolving stage intussuseption, annular conducting layer with light electric connection, the motor chamber has been seted up to the downside in rotatory chamber, the motor has set firmly on the right wall in motor chamber, the left side power connection of motor is equipped with the motor shaft, the third bevel gear has set firmly on the left surface of motor shaft, rotation axis downwardly extending part stretches into the motor intracavity, and its bottom surface has set firmly fourth bevel gear, fourth bevel gear with the meshing of third bevel gear.

7. The tidal energy ocean guidance lighthouse of claim 5, wherein: a conductive layer is fixedly embedded in the tower body and communicated with the magnetic induction coil, the motor and the annular conductive layer.

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