CN111927692B

CN111927692B - Environment-friendly wave generator

Info

Publication number: CN111927692B
Application number: CN202010850389.4A
Authority: CN
Inventors: 张浩斌; 丁乐旗
Original assignee: Individual
Current assignee: Zhang Haobin
Priority date: 2020-08-21
Filing date: 2020-08-21
Publication date: 2021-03-12
Anticipated expiration: 2040-08-21
Also published as: CN111927692A

Abstract

The invention discloses an environment-friendly wave power generator which comprises a floating shell and three groups of floating devices which are fixedly arranged on the left side surface of the floating shell at equal intervals, wherein each floating device comprises a first connecting rod which is rotatably connected and arranged on the left side surface of the floating shell, and a connecting block is fixedly arranged on the left side surface of the first connecting rod; the movable type power generation device is simple in structure and convenient to use, the movable type power generation device can be arranged movably, the position of the movable type power generation device can be freely selected, the place can be freely changed according to various factors, and the problem that the site selection of power generation equipment is difficult to construct is solved; meanwhile, the invention can also recover garbage in seawater while generating power by using ocean energy, and plays a certain role in treating pollution of the sea.

Description

Environment-friendly wave generator

Technical Field

The invention relates to the technical field of ocean power generation, in particular to an environment-friendly wave power generator.

Background

The ocean, which accounts for 71% of the total global area, has a great energy, and the impact force of ocean waves is very great, so that the utilization of ocean energy is a good choice. However, compared with wind energy and solar energy technologies, wave energy power generation technologies are behind for a decade. The wave power generation power supply is a power supply manufactured by utilizing wave power generation, and has a plurality of advantages for supplying power to the ocean sensing node. In order to increase the profit of the power generation equipment to a value larger than the resource consumed for installation of the equipment, it is necessary to install the power generation equipment in a sea area with much waves and to improve the power generation efficiency. However, in some times of intense ocean current movement, the following natural disasters may occur in the sea areas with much waves, which may damage equipment, and therefore, the wave energy generator should be arranged in a place with much waves and safety. For this reason, the location of the device is very important and difficult.

Disclosure of Invention

The invention aims to provide an environment-friendly wave power generator, which is used for overcoming the defects in the prior art.

The invention relates to an environment-friendly wave power generator, which comprises a floating shell and three groups of floating devices which are fixedly arranged on the left side surface of the floating shell at equal intervals, wherein each floating device comprises a first connecting rod which is rotatably connected with the left side surface of the floating shell, a connecting block is fixedly arranged on the left side surface of the first connecting rod, the right side surface of the connecting block below the first connecting rod is rotatably connected with a first hydraulic pipe, the first hydraulic pipe is slidably connected and arranged in a first hydraulic pump fixedly arranged on the left side surface of the floating shell, a second connecting rod is fixedly arranged on the left side surface of the connecting block, the tail end of the second connecting rod is rotatably connected with a rotating disc, the bottom surface of the rotating disc is in threaded connection with a base, the bottom surface of the base is in threaded connection with a floating disc, a power generation device is fixedly arranged on the left side surface of the floating shell below, the floating shell is internally provided with a collecting cavity, a filter screen is fixedly arranged in the collecting cavity, the top surface of the filter screen is provided with an inlet pipe penetrating through the left side surface of the floating shell, the bottom surface of the collecting cavity is communicated with a drainage cavity through a first drainage pipe, the left side of the drainage cavity is provided with a hydraulic pump II, the hydraulic pump II is communicated with the hydraulic pump I, the collecting cavity is internally connected with a piston plate fixedly connected with the hydraulic pump II through a hydraulic pipe II in a sliding manner, the right side surface of the drainage cavity is communicated with a water outlet pipe penetrating through the bottom surface of the floating shell, the water outlet pipe is provided with a one-way valve I, the one-way valve I allows seawater to flow in the water outlet pipe from top to bottom, a safety net is arranged in the water outlet pipe, a water storage cavity is arranged in the floating shell, a water through pipe is fixedly, be equipped with the ball valve in the water service pipe, it is equipped with the water level tank to run through in the showy shell before, the water level inslot is equipped with and can control ball valve pivoted adjusting device, it is equipped with the constant head tank to run through in the showy shell bottom, the constant head tank rear side is equipped with the motor, motor leading flank installs first axis of rotation, first axis of rotation extends to in the constant head tank and with the constant head tank antetheca rotates to be connected, set firmly down the wheel on the first axis of rotation, it has the iron chain to wind on the lower wheel, the iron chain end sets firmly the location anchor.

Optionally, the power generation device comprises three power generation shells fixedly arranged on the left side surface of the floating shell, a power generation cavity is arranged in each power generation shell, a hydraulic pump III is fixedly arranged on the rear wall of each power generation cavity, a hydraulic pipe III penetrating through the top surface of each power generation shell is slidably arranged on the top surface of each hydraulic pump III, the hydraulic pipe III is rotatably connected with the floating disc, two rotation boxes with symmetrical front and back positions are fixedly arranged on the bottom wall of each power generation cavity on the right side of each hydraulic pump III, a first rotation cavity is arranged in each rotation box and is rotatably connected with fan blades, the front and back first rotation cavities are communicated through a first connecting shaft arranged in the right wall of each first rotation cavity, a power generator is arranged between the front and back rotation connecting pipes and is connected with the fan blades in the rotation boxes on the front side through a second rotation shaft, and the power generator is connected with the fan blades in the rotation boxes on the back side through a third rotation shaft, the first rotating cavity is communicated with the third hydraulic pump through a second connecting pipe, a second one-way valve is arranged on the second connecting pipe, the second one-way valve on the front side only allows water in the second connecting pipe to flow from left to right, and the second one-way valve on the rear side only allows water in the second connecting pipe to flow from right to left.

Optionally, the adjusting device comprises a second rotating cavity arranged above the water level groove, a fourth rotating shaft is rotatably connected to the front wall of the second rotating cavity, a gear is fixedly arranged on the fourth rotating shaft, a rack rod meshed with the gear is slidably connected to the bottom wall of the second rotating cavity, the rack rod extends downwards into the water level groove, a buoyancy ball is fixedly arranged at the bottom end of the rack rod, the fourth rotating shaft extends into the water pipe and is fixedly connected with the front side face of the ball valve, an anti-falling block is fixedly arranged at the top end of the rack rod, when the floating shell descends in the sea, seawater can enter the water level groove, after the water level in the water level groove rises, the seawater can drive the buoyancy ball to move upwards, the gear is driven to rotate by the rack rod, and the gear drives the ball valve to rotate through the fourth rotating shaft to slowly close the water pipe, when the water service pipe is completely closed, seawater cannot enter the water storage cavity, the floating shell floats on the sea surface, the inlet pipe is kept slightly higher than the sea surface, the seawater cannot enter the collection cavity through the inlet pipe when no waves exist, and garbage can enter the collection cavity along with the waves when the waves exist.

Optionally, a communicating groove penetrating through the left side face of the floating shell is formed in the left side face of the collecting cavity in a communicating mode, and an arc-shaped sealing door is arranged in the communicating groove.

Optionally, a sealing sleeve is arranged on the hydraulic pipe III in the power generation shell wall.

The invention has the beneficial effects that: the movable type power generation device is simple in structure and convenient to use, the movable type power generation device can be arranged movably, the position of the movable type power generation device can be freely selected, the place can be freely changed according to various factors, and the problem that the site selection of power generation equipment is difficult to construct is solved; meanwhile, the invention can recover garbage in seawater while generating power by using ocean energy, discharges the seawater by moving the floating disc by means of a hydraulic device, improves the recovery amount of the garbage, plays a certain role in controlling the pollution of the sea, and has the advantage of environmental protection compared with other power generation equipment.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

Fig. 1 is a schematic structural diagram of an environment-friendly wave power generator of the present invention;

FIG. 2 is a schematic view of the structure at A-A in FIG. 1;

FIG. 3 is a schematic view of the structure at B-B in FIG. 1;

FIG. 4 is a schematic view of the structure at C-C in FIG. 1.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 4, an environment-friendly wave power generator according to an embodiment of the present invention includes a floating housing 11 and three sets of floating devices 101 fixed on a left side surface of the floating housing 11 at equal intervals, where the floating devices 101 include a first connecting rod 12 rotatably connected to the left side surface of the floating housing 11, a connecting block 13 is fixed on a left side surface of the first connecting rod 12, a hydraulic pipe 16 is rotatably connected to a right side surface of the connecting block 13 below the first connecting rod 12, the hydraulic pipe 16 is slidably connected to and installed in a hydraulic pump 15 fixed on the left side surface of the floating housing 11, a second connecting rod 14 is fixed on a left side surface of the connecting block 13, a rotating disc 17 is rotatably connected to a tail end of the second connecting rod 14, a base 18 is screwed to a bottom surface of the rotating disc 17, a floating disc 19 is screwed to a bottom surface of the base 18, and a power generation device 103 is fixed on a left side surface of the floating housing 11, the floating disc 19 can generate electricity through the power generation device 103 when moving up and down along with waves, a collection cavity 31 is arranged in the floating shell 11, a filter screen 47 is fixedly arranged in the collection cavity 31, the top surface of the filter screen 47 is provided with an inlet pipe 30 penetrating through the left side surface of the floating shell 11, the bottom surface of the collection cavity 31 is provided with a drainage cavity 38 through a first drainage pipe 46, the left side of the drainage cavity 38 is provided with a second hydraulic pump 35, the second hydraulic pump 35 is communicated with a first hydraulic pump 15, a piston plate 37 fixedly connected with the second hydraulic pump 35 through a second hydraulic pipe 36 is slidably connected in the collection cavity 31, the right side surface of the drainage cavity 38 is communicated with a water outlet pipe 44 penetrating through the bottom surface of the floating shell 11, a one-way valve 43 is arranged on the water outlet pipe 44, a safety net 45 is arranged in the water outlet pipe 44, a water pipe 49 is fixedly arranged in the top wall of the water storage cavity 50, the water pipe 49 penetrates through the bottom surface of the floating shell 11 and a water pump 57 is arranged on the water pipe 49, a ball valve 55 is arranged in the water pipe 49, a water level groove 48 is arranged in the floating shell 11 in a penetrating manner, a regulating device 102 capable of controlling the rotation of the ball valve 55 is arranged in the water level groove 48, a positioning groove 39 is arranged in the bottom surface of the floating shell 11 in a penetrating manner, a motor 59 is arranged on the rear side of the positioning groove 39, a first rotating shaft 58 is installed on the front side surface of the motor 59, the first rotating shaft 58 extends into the positioning groove 39 and is rotatably connected with the front wall of the positioning groove 39, a lower rotating wheel 42 is fixedly arranged on the first rotating shaft 58, an iron chain 41 is wound on the lower rotating wheel 42, and a positioning anchor.

Preferably, the power generation device 103 includes three power generation shells 23 fixedly arranged on the left side surface of the floating shell 11, a power generation cavity 24 is arranged in the power generation shell 23, a hydraulic pump third 22 is fixedly arranged on the rear wall of the power generation cavity 24, a hydraulic pipe third 20 penetrating through the top surface of the power generation shell 23 is slidably mounted on the top surface of the hydraulic pump third 22, the hydraulic pipe third 20 is rotatably connected with the floating disc 19, two rotation boxes 27 symmetrical in front and rear positions are fixedly arranged on the bottom wall of the power generation cavity 24 on the right side of the hydraulic pump third 22, a first rotation cavity 29 is arranged in the rotation box 27, the first rotation cavity 29 is connected with a rotation blade 28, the front rotation cavity 29 and the rear rotation cavity 29 are communicated through a first connection pipe 34 arranged in the right wall of the first rotation cavity 29, a power generator 52 is arranged between the front rotation box 27 and the rear rotation box 27, the power generator 52 is connected with the rotation blade 28 in the rotation box 27 on the front side through a second rotation, the generator 52 is connected with the fan blades 28 in the rotating box 27 at the rear side through a third rotating shaft 53, the first rotating cavity 29 is communicated with the hydraulic pump III 22 through a second connecting pipe 25, the second connecting pipe 25 is provided with a check valve II 26, the check valve II 26 at the front side only allows water in the second connecting pipe 25 to flow from left to right, the check valve II 26 at the rear side only allows water in the second connecting pipe 25 to flow from right to left, when the floating disc 19 moves downwards, the hydraulic pipe III 20 is driven to move downwards in the hydraulic pump III 22, the water in the hydraulic pump III 22 enters the first rotating cavity 29 at the front side through the second connecting pipe 25 at the front side, the water flow drives the fan blades 28 at the front side to rotate anticlockwise, and the fan blades 28 rotate through the second rotating shaft 51 to generate electricity in the generator 52, when the floating disc 19 moves upwards, the hydraulic pipe III 20 is driven to move upwards in the hydraulic pump III 22, at the moment, water in the first rotating cavity 29 on the front side enters the first rotating cavity 29 on the rear side through the first connecting pipe 34 and then flows into the hydraulic pump III 22 again through the second connecting pipe 25 on the rear side, water flow can drive the fan blades 28 on the rear side to rotate clockwise when flowing in the first rotating cavity 29 on the rear side, the fan blades 28 rotate through the third rotating shaft 53 to generate electricity in the generator 52, when the floating disc 19 moves vertically, the fan blades 28 on the front and the rear sides can be respectively driven to rotate to generate electricity in the generator 52, and the electricity generation efficiency is improved.

Preferably, the adjusting device 102 includes a second rotating cavity 54 disposed above the water level groove 48, a fourth rotating shaft 56 is rotatably connected to the front wall of the second rotating cavity 54, a gear 62 is fixedly disposed on the fourth rotating shaft 56, a rack rod 61 engaged with the gear 62 is slidably connected to the bottom wall of the second rotating cavity 54, the rack rod 61 extends downward into the water level groove 48 and a buoyancy ball 60 is fixedly disposed at the bottom end of the rack rod 61, the fourth rotating shaft 56 extends into the water pipe 49 and is fixedly connected to the front side surface of the ball valve 55, an anti-dropping block 63 is fixedly disposed at the top end of the rack rod 61, when the floating shell 11 descends in the sea, seawater enters the water level groove 48, and when the water level in the water level groove 48 rises, the rack rod 61 drives the gear 62 to rotate, the gear 62 drives the ball valve 55 to rotate through the fourth rotating shaft 56 to slowly close the water service pipe 49, when the water service pipe 49 is completely closed, seawater cannot enter the water storage cavity 50, at this time, the floating shell 11 floats on the sea surface, and the inlet pipe 30 is kept slightly higher than the sea surface, so that the seawater cannot enter the collection cavity 31 through the inlet pipe 30 when no wave exists, and garbage can enter the collection cavity 31 along with the wave when the wave exists.

Preferably, a communication groove 32 penetrating through the left side surface of the floating shell 11 is arranged in the left side surface of the collection chamber 31 in a communication manner, an arc-shaped sealing door 33 is arranged in the communication groove 32, the garbage collected in the collection chamber 31 can be taken out through the communication groove 32, and the communication groove 32 can be sealed by the sealing door 33 to prevent seawater from entering the collection chamber 31.

Preferably, a sealing sleeve 21 is arranged on the hydraulic pipe III 20 in the wall of the power generation shell 23, and the sealing sleeve 21 can prevent seawater from entering the power generation cavity 24.

In the initial state, there is no water in the water storage chamber 50, the iron chain 41 is wound around the lower pulley 42, the piston plate 37 is located at the leftmost side of the drain chamber 38, and the ball valve 55 opens the water pipe 49.

When power generation work is required, the floating shell 11 is placed offshore, the water pump 57 is started to flow seawater into the water storage cavity 50 through the water service pipe 49, the seawater enters the water storage cavity 50 to cause the gravity of the floating shell 11 to increase, the floating shell 11 moves downwards, the seawater enters the water level tank 48 and then carries the buoyancy ball 60 to move upwards, the ball valve 55 is slowly closed to slow the entering speed of the seawater, and after the ball valve 55 is completely closed, the floating shell 11 stops descending, the sea level is slightly lower than the inlet pipe 30, and the floating disc 19 floats on the sea level;

then the motor 59 is started to drive the lowering wheel 42 to rotate through the first rotating shaft 58 to pay out the iron chain 41, the positioning anchor 40 moves downwards under the action of gravity, the positioning anchor 40 falls on the sea bottom to fix the floating shell 11 to prevent the floating shell 11 from floating away along with the sea waves;

when waves pass through the floating disc 19, the floating disc 19 is driven to move up and down, the floating disc 19 drives the hydraulic pipe III 20 to move up and down, and power is generated in the generator 52.

When garbage moves to the periphery of the floating shell 11 along with seawater, the garbage can enter the collection cavity 31 through the inlet pipe 30 under the action of waves, the seawater can enter the drainage cavity 38 through the filter screen 47, the garbage can be remained in the collection cavity 31 due to the blocking of the filter screen 47, when the floating disc 19 moves up and down, the first hydraulic pipe 16 can be driven to move in the first hydraulic pump 15 through the second connecting rod 14 and the connecting block 13, and the second hydraulic pipe 36 can be driven to move left and right when the floating disc 19 moves up and down due to the communication between the first hydraulic pump 15 and the second hydraulic pump 35, and the second hydraulic pipe 36 drives the piston plate 37 to move so as to discharge the water in the drainage cavity 38 through the water outlet pipe 44.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides an environment-friendly wave generator, including float the shell with equidistant set firmly in float three floating installation of group of shell left surface, its characterized in that: the floating device comprises a first connecting rod which is rotatably connected and arranged on the left side surface of the floating shell, a connecting block is fixedly arranged on the left side surface of the first connecting rod, the right side surface of the connecting block below the first connecting rod is rotatably connected with a first hydraulic pipe, the first hydraulic pipe is slidably connected and arranged in a first hydraulic pump fixedly arranged on the left side surface of the floating shell, a second connecting rod is fixedly arranged on the left side surface of the connecting block, the tail end of the second connecting rod is rotatably connected with a rotating disc, the bottom surface of the rotating disc is in threaded connection with a base, the bottom surface of the base is in threaded connection with a floating disc, a power generation device is fixedly arranged on the left side surface of the floating shell below the floating disc, the floating disc can generate power through the power generation device when moving up and down along with waves, a collecting cavity is arranged in the floating shell, a filter screen is, the bottom surface of the collecting cavity is communicated with a water drainage cavity through a first water drainage pipe, the left side of the water drainage cavity is provided with a second hydraulic pump, the second hydraulic pump is communicated with the first hydraulic pump, the collecting cavity is connected with a piston plate fixedly connected with the second hydraulic pump through a hydraulic pipe in a sliding manner, the right side surface of the water drainage cavity is communicated with a water outlet pipe penetrating through the bottom surface of the floating shell, the water outlet pipe is provided with a first one-way valve, the first one-way valve allows seawater to flow from top to bottom in the water outlet pipe, a safety net is arranged in the water outlet pipe, a water storage cavity is arranged in the floating shell, a water through pipe is fixedly arranged in the top wall of the water storage cavity, the water through pipe penetrates through the bottom surface of the floating shell, a water pump is arranged on the water through pipe, a ball valve is arranged in the water through pipe, the floating shell bottom surface runs through in and is equipped with the constant head tank, the constant head tank rear side is equipped with the motor, motor leading flank installs first axis of rotation, first axis of rotation extends to in the constant head tank and with the constant head tank antetheca rotates and is connected, the wheel is transferred to having set firmly in the first axis of rotation, transfer and take turns to around there being the iron chain, the iron chain end sets firmly the location anchor.

2. The environment-friendly wave power generator as claimed in claim 1, wherein: the power generation device comprises three power generation shells fixedly arranged on the left side surface of the floating shell, a power generation cavity is arranged in each power generation shell, a hydraulic pump III is fixedly arranged on the rear wall of each power generation cavity, a hydraulic pipe III penetrating through the top surface of each power generation shell is slidably arranged on the top surface of each hydraulic pump III, the hydraulic pipe III is rotatably connected with the floating disc, two rotating boxes which are symmetrical in front and back positions are fixedly arranged on the bottom wall of each power generation cavity on the right side of each hydraulic pump III, a first rotating cavity is arranged in each rotating box and is rotatably connected with fan blades, the front rotating cavity and the rear rotating cavity are communicated through a first connecting pipe arranged in the right wall of the first rotating cavity, a power generator is arranged between the front rotating box and the rear rotating box, the power generator is connected with the fan blades in the rotating boxes on the front side through a second rotating shaft, and the power generator is connected with the fan blades in the rotating boxes on the rear side through, the first rotating cavity is communicated with the third hydraulic pump through a second connecting pipe, a second one-way valve is arranged on the second connecting pipe, the second one-way valve on the front side only allows water in the second connecting pipe to flow from left to right, and the second one-way valve on the rear side only allows water in the second connecting pipe to flow from right to left.

3. The environment-friendly wave power generator as claimed in claim 1, wherein: the adjusting device comprises a second rotating cavity arranged above the water level groove, a fourth rotating shaft is rotatably connected to the front wall of the second rotating cavity, a gear is fixedly arranged on the fourth rotating shaft, a rack rod meshed with the gear is slidably connected to the bottom wall of the second rotating cavity, the rack rod extends downwards into the water level groove, a buoyancy ball is fixedly arranged at the bottom end of the rack rod, the fourth rotating shaft extends into the water pipe and is fixedly connected with the front side face of the ball valve, an anti-falling block is fixedly arranged at the top end of the rack rod, when the floating shell descends in the sea, seawater can enter the water level groove, after the water level in the water level groove rises, the buoyancy ball can be driven to move upwards, the gear rotates under the driving of the rack rod, and the gear drives the ball valve to rotate through the fourth rotating shaft to slowly close the water pipe, when the water service pipe is completely closed, seawater cannot enter the water storage cavity, the floating shell floats on the sea surface, the inlet pipe is kept slightly higher than the sea surface, the seawater cannot enter the collection cavity through the inlet pipe when no waves exist, and garbage can enter the collection cavity along with the waves when the waves exist.

4. The environment-friendly wave power generator as claimed in claim 1, wherein: the inner side of the left side face of the collecting cavity is communicated with a communicating groove which penetrates through the left side face of the floating shell, and an arc-shaped sealing door is arranged in the communicating groove.

5. The environment-friendly wave power generator as claimed in claim 2, wherein: and a sealing sleeve is arranged on the hydraulic pipe III in the wall of the power generation shell.