CN110984353A - Hydroelectric generation device adjusted according to precipitation - Google Patents
Hydroelectric generation device adjusted according to precipitation Download PDFInfo
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- CN110984353A CN110984353A CN202010001315.3A CN202010001315A CN110984353A CN 110984353 A CN110984353 A CN 110984353A CN 202010001315 A CN202010001315 A CN 202010001315A CN 110984353 A CN110984353 A CN 110984353A
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- block
- groove
- chute
- water storage
- wall
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- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03F—SEWERS; CESSPOOLS
- E03F5/00—Sewerage structures
- E03F5/10—Collecting-tanks; Equalising-tanks for regulating the run-off; Laying-up basins
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- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03F—SEWERS; CESSPOOLS
- E03F5/00—Sewerage structures
- E03F5/10—Collecting-tanks; Equalising-tanks for regulating the run-off; Laying-up basins
- E03F5/105—Accessories, e.g. flow regulators or cleaning devices
- E03F5/107—Active flow control devices, i.e. moving during flow regulation
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03B—MACHINES OR ENGINES FOR LIQUIDS
- F03B13/00—Adaptations of machines or engines for special use; Combinations of machines or engines with driving or driven apparatus; Power stations or aggregates
Abstract
The invention discloses a hydroelectric generation device adjusted according to rainfall, which comprises a box body, wherein an opening mechanism is arranged on the top wall of the box body, a right water falling groove with an upward opening is arranged on the top wall of the right end of the box body, a first chute with a leftward opening is fixedly arranged on the left end wall of the right water falling groove, the left end wall and the right end wall of the first chute are fixedly connected with inclined pipes symmetrically arranged left and right, a flow dividing mechanism is arranged at the first chute, one end of each inclined pipe, which is far away from the first chute, is fixedly connected with a water storage ring, water inclining mechanisms are symmetrically arranged left and right at the front ends of the left and right water storage rings, a left water falling groove with a downward opening is arranged on the left end wall of the first chute, the left end wall of the left water storage ring is fixedly connected with the left water falling groove, power generation mechanisms are symmetrically arranged on the lower sides of the left, and the shunting power generation mechanism can be started when the precipitation is too large, so that the device damage caused by the too large precipitation is prevented.
Description
Technical Field
The invention relates to the technical field of power generation, in particular to a hydroelectric power generation device adjusted according to precipitation.
Background
In the power generation, the power generation power device is used to convert water energy, heat energy of fossil fuel (coal, oil, natural gas, etc.), nuclear energy, solar energy, wind energy, geothermal energy, ocean energy, etc. into electric energy. Fossil fuels are used for power generation at the end of the 20 th century, but the resources of the fossil fuels are scarce and gradually exhausted, and people gradually use renewable energy sources to generate power.
Can utilize precipitation to carry out hydroelectric power generation, but often can not accumulate required water yield and make turbine rotation electricity generation again when precipitation electricity generation now, the device can damage because the water yield is too big moreover when the precipitation is too big, and very inefficiency and cost are big.
Disclosure of Invention
Aiming at the technical defects, the invention provides a hydroelectric power generation device adjusted according to precipitation, which can overcome the defects.
The invention relates to a hydroelectric generation device adjusted according to precipitation, which comprises a box body, wherein the top wall of the box body is provided with an upward-opening chute, the bottom wall of the upward chute is provided with a turbine groove with an upward opening, the top wall of the box body is provided with an opening mechanism, the top wall of the right end of the box body is provided with a right water falling groove with an upward opening, the left end wall of the right water falling groove is fixedly provided with a first chute with a leftward opening, the left and right end walls of the first chute are fixedly connected with inclined pipes which are symmetrically arranged leftwards and rightwards, a diversion mechanism is arranged at the first chute, one end of each inclined pipe, far away from the first chute, is fixedly connected with a water storage ring, the end wall of the right water passing pipe, close to the first chute, is provided with a second chute which is communicated leftwards and rightwards, the second chute is communicated with the inclined pipe, the bottom end of, the right side retaining ring right-hand member wall and the right side groove right-hand member wall fixed connection that falls into water, first chute left end wall is provided with the downward left side groove that falls into water of opening, and the left side retaining ring left end wall and the left side groove fixed connection that falls into water control retaining ring downside bilateral symmetry are provided with power generation mechanism, the right side groove that falls into water and the left side groove diapire that falls into water are provided with water storage mechanism.
Preferably, the opening mechanism comprises a second turbine arranged in a turbine groove, a left water pipe with an upward opening is arranged on the bottom wall of the turbine groove, a right water pipe with a rightward opening is arranged at the bottom end of the right end wall of the left water pipe, the right end wall of the right water pipe is fixedly connected with the water storage ring and is communicated with the inside of the water storage ring, the right end wall of the second turbine is fixedly connected with a second turbine shaft, the second turbine shaft is rotatably connected with the box body, the right end of the second turbine shaft is fixedly connected with a first gear, a winder is fixedly arranged at the right end of the first gear, the winder and the first gear are positioned in a winder cavity, a top rope is wound on the winder, a rope pulling groove with an upward opening is arranged on the top wall of the winder cavity, a first rotating wheel is fixedly connected between the front end wall and the rear end wall of the rope pulling groove, a top block is fixedly arranged on the top wall, and, fixedly connected with second runner between the end wall around the second spout left end, the second spout shelters from a piece sliding connection with the top, the top stay cord other end is walked around first runner and second runner in proper order and is sheltered from a piece left end wall fixed connection with the top, second spout roof is provided with the first spout that the opening is decurrent, the top is sheltered from a fixed first slider that is provided with of piece roof, first slider is located first spout and rather than sliding connection, through first spring coupling between first slider right-hand member wall and the first spout right-hand member wall.
Preferably, the shunting mechanism is including setting up in first chute roof and the downward third spout of opening, third spout and reposition of redundant personnel dog sliding connection, through second spring coupling between reposition of redundant personnel dog roof and the third chute roof, reposition of redundant personnel dog below is provided with the centrifugal piece chamber that is located first chute downside, be provided with centrifugal piece in the centrifugal piece chamber, be provided with centrifugal chamber in the centrifugal piece, centrifugal piece and the push rod sliding connection of evenly setting, push rod inner is located centrifugal chamber, and is relative pass through third spring coupling between the push rod, the upper end the push rod is located reposition of redundant personnel dog diapire below, centrifugal piece and first turbine shaft fixed connection, first turbine shaft rotates with the box to be connected, first turbine shaft right-hand member and the first turbine fixed connection that is located the right side inslot that falls into water.
Preferably, the water-pouring mechanism comprises an upper rotating groove which is arranged at the top end of the front side of the water storage ring and has an upward opening, a second rotating shaft is fixedly connected between the left end wall and the right end wall of the upper rotating groove, the second rotating shaft is connected with the upper rotating groove through a torsion spring, the second rotating shaft is rotatably connected with a rotating rod, floats are symmetrically and fixedly arranged at the front end and the rear end of the rotating rod in a front-back manner, the floats at the front side are positioned in a transfer groove with a backward opening, a first inclined block groove with an upward opening is arranged at the bottom wall of the transfer groove, the first inclined block groove is slidably connected with a first inclined block, the top end of the first inclined block is positioned in the transfer groove, a second sliding block is fixedly arranged at the right end wall of the first inclined block, the second sliding block is positioned in a fourth sliding groove and slidably connected with the fourth sliding groove, the bottom wall of the second sliding block is connected with the bottom wall of the fourth sliding, a first rotating shaft is fixedly connected between the left end wall and the right end wall of the lower rotating groove, the water storage rotating block is rotatably connected with the first rotating shaft, the bottom wall of the front side of the water storage rotating block is connected with the bottom wall of the lower rotating groove through a fourth spring, a fifth sliding groove which is communicated up and down is arranged at the left part of the water storage rotating block, the fifth sliding groove is slidably connected with a first inclined block, the bottom wall of the first inclined block is slidably connected with a second inclined block, the second inclined block is positioned in a second inclined block groove with a right opening and is slidably connected with the second inclined block groove, a third sliding block is fixedly arranged on the bottom wall of the second inclined block, the third sliding block is positioned in a sixth sliding groove and is slidably connected with the sixth sliding groove, and a sixth spring is arranged between the left end wall of the; and the second oblique block left end wall is connected with the push block in a sliding manner, the push block top wall is contacted with the water storage rotating block bottom wall, the spring block is fixedly arranged on the push block left end wall, and the spring block bottom wall is connected with the lower rotating block bottom wall through a seventh spring.
Preferably, the power generation mechanism includes the third turbine that sets up in retaining commentaries on classics piece downside, third turbine rear end wall and third turbine shaft fixed connection, the third turbine shaft rotates with the box to be connected, third turbine shaft rear end is provided with the gearbox, the gearbox rear end is provided with the output shaft, the output shaft rotates with the box to be connected, output shaft rear end wall is connected with generator power.
Preferably, the water storage mechanism includes a water storage tank arranged on the bottom wall of the left water falling groove and the right water falling groove, the water storage tank is connected with the tank body in a sliding manner, the rear end wall of the water storage tank is fixedly connected with a pull ring, a water storage chamber is arranged in the water storage tank, the top wall of the water storage chamber is provided with a left water falling opening which is located on the lower side of the left water falling opening and is provided with an upward opening, and the top wall of the water storage chamber is provided with a right water falling opening.
The beneficial effects are that: the device can start accumulated water when raining, discharge water when a certain water storage amount is reached for power generation, and can start the shunt power generation mechanism when the rainfall is overlarge to prevent the device from being damaged due to overlarge rainfall, wherein the opening mechanism can start power generation when the rainfall is overlarge, shield dust prevention is performed when the rainfall is not rainfall to reduce the damage or aging degree of the device, the shunt mechanism can shunt when the rainfall is overlarge to prevent mechanical damage due to overlarge rainfall, the water dumping mechanism can automatically discharge water after water storage for power generation, and the water storage mechanism can store the rainfall.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.
FIG. 1 is a schematic view of a hydroelectric power plant according to the present invention, regulated according to precipitation;
FIG. 2 is a schematic view of A-A in FIG. 1 according to an embodiment of the present invention;
FIG. 3 is a schematic view of B-B in FIG. 1 according to an embodiment of the present invention;
FIG. 4 is a schematic view of C-C in FIG. 2 according to an embodiment of the present invention.
Detailed Description
All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.
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.
The hydroelectric generation device of the device according to the invention is adjusted according to precipitation, which comprises a box body 1, wherein the top wall of the box body 1 is provided with an upward-opening upper chute 54, the bottom wall of the upper chute 54 is provided with a turbine groove 55 with an upward opening, the top wall of the box body 1 is provided with an opening mechanism, the top wall of the right end of the box body 1 is provided with a right water falling groove 18 with an upward opening, the left end wall of the right water falling groove 18 is fixedly provided with a first chute 13 with a leftward opening, the left and right end walls of the first chute 13 are fixedly connected with inclined pipes 21 which are symmetrically arranged left and right, the first chute 13 is provided with a flow dividing mechanism, one end of the inclined pipe 21 far away from the first chute 13 is fixedly connected with a water storage ring 30, the end wall of the right water passing pipe 31 close to the first chute 13 is provided with a second chute 20 which is communicated left and right, the second chute 20 is communicated with, control it is provided with the mechanism of falling water to hold water ring 30 front end bilateral symmetry, the right side hold water ring 30 right side end wall and the right side 18 right-hand member walls fixed connection that fall into water groove, first chute 13 left side end wall is provided with the left side groove 29 that falls into water that open side down, and the left side hold water ring 30 left side end wall and the left side groove 29 fixed connection that falls into water, control it is provided with power generation facility to hold water ring 30 downside bilateral symmetry, the right side groove 18 that falls into water and the left side groove 29 diapire that falls into water are provided with the mechanism of falling water.
Beneficially, the opening mechanism includes a second turbine 56 disposed in the turbine groove 55, the bottom wall of the turbine groove 55 is provided with a left water pipe 57 with an upward opening, the bottom end of the right end wall of the left water pipe 57 is provided with a right water pipe 31 with a rightward opening, the right end wall of the right water pipe 31 is fixedly connected with and internally communicated with the water storage ring 30, the right end wall of the second turbine 56 is fixedly connected with a second turbine shaft 33, the second turbine shaft 33 is rotatably connected with the box body 1, the right end of the second turbine shaft 33 is fixedly connected with a first gear 32, the right end of the first gear 32 is fixedly provided with a winder 34, the winder 34 and the first gear 32 are located in a winder cavity 35, the top rope 3 is wound on the winder 34, the top wall of the winder cavity 35 is provided with a rope pulling groove 36 with an upward opening, the first runner 2 is fixedly connected between the front end wall and the rear end wall of the rope pulling groove 36, the fixed kicking block 7 that is provided with of 1 roof of box, communicating second spout 6 about is provided with in the kicking block 7, fixedly connected with second runner 4 between the end wall around the 6 left ends of second spout, second spout 6 shelters from piece 8 sliding connection with the top, the 3 other ends of top stay cord walk around first runner 2 and second runner 4 in proper order and hide dog 8 left end wall fixed connection with the top, 6 roofs of second spout are provided with the first spout 5 that open side down, the top hides the fixed first slider 9 that is provided with of dog 8 roof, first slider 9 is located first spout 5 and rather than sliding connection, be connected through first spring 10 between first slider 9 right-hand member wall and the 5 right-hand member walls of first spout.
Advantageously, the diverting mechanism comprises a third chute 11, which is arranged on the top wall of the first chute 13 and opens downwards, the third sliding chute 11 is connected with a shunt stop 14 in a sliding way, the top wall of the shunt stop 14 is connected with the top wall of the third sliding chute 11 through a second spring 12, below said diverter stop 14 is arranged a centrifugal mass chamber 25 located on the lower side of the first chute 13, a centrifugal block 24 is arranged in the centrifugal block cavity 25, a centrifugal cavity 23 is arranged in the centrifugal block 24, the centrifugal blocks 24 are connected with push rods 15 which are uniformly arranged in a sliding way, the inner ends of the push rods 15 are positioned in a centrifugal cavity 23, the opposite push rods 15 are connected through a third spring 22, the push rod 15 at the upper end is positioned below the bottom wall of the flow dividing stop block 14, the centrifugal block 24 is fixedly connected with a first turbine shaft 17, the first turbine shaft 17 is rotatably connected with the box body 1, the right end of the first turbine shaft 17 is fixedly connected with a first turbine 16 positioned in a right water dropping groove 18.
Beneficially, the water-pouring mechanism includes an upper rotating groove 37 disposed at the top end of the front side of the water storage ring 30 and having an upward opening, a second rotating shaft 50 is fixedly connected between the left and right end walls of the upper rotating groove 37, the second rotating shaft 50 is connected with the upper rotating groove 37 through a torsion spring 51, the second rotating shaft 50 is rotatably connected with a rotating rod 52, the front and rear ends of the rotating rod 52 are symmetrically and fixedly provided with floats 53, the front float 53 is located in a middle rotating groove 49 having a backward opening, the bottom wall of the middle rotating groove 49 is provided with a first inclined block groove 64 having an upward opening, the first inclined block groove 64 is slidably connected with a first inclined block 58, the top end of the first inclined block 58 is located in the middle rotating groove 49, the right end wall of the first inclined block 58 is fixedly provided with a second sliding block 59, the second sliding block 59 is located in a fourth sliding groove 61 and slidably connected therewith, the bottom wall of the second sliding block 59 is connected with the bottom wall of the fourth sliding groove 61 through a fifth spring, the front end of the water storage rotating block 40 is positioned in the lower rotating groove 48, a first rotating shaft 39 is fixedly connected between the left end wall and the right end wall of the lower rotating groove 48, the water storage rotating block 40 is rotatably connected with the first rotating shaft 39, the bottom wall of the front side of the water storage rotating block 40 is connected with the bottom wall of the lower rotating groove 48 through a fourth spring 47, a fifth sliding groove 62 which is communicated up and down is arranged at the left part of the water storage rotating block 40, the fifth sliding groove 62 is slidably connected with a first inclined block 58, the bottom wall of the first inclined block 58 is slidably connected with a second inclined block 65, the second inclined block 65 is positioned in a second inclined block groove 69 with a right opening and is slidably connected with the second inclined block groove, a third sliding block 66 is fixedly arranged at the bottom wall of the second inclined block 65, the third sliding block 66 is positioned in a sixth sliding groove 68 and is slidably connected with the sixth sliding groove 68, and a sixth spring 67 is arranged between the left end; and the left end wall of the second inclined block 65 is connected with the push block 70 in a sliding manner, the top wall of the push block 70 is contacted with the bottom wall of the water storage rotating block 40, the left end wall of the push block 70 is fixedly provided with a spring block 72, and the bottom wall of the spring block 72 is connected with the bottom wall of the lower chute 48 through a seventh spring 71.
Advantageously, the power generating mechanism comprises a third turbine 41 arranged on the lower side of the water accumulating rotary block 40, the rear end wall of the third turbine 41 is fixedly connected with a third turbine shaft 42, the third turbine shaft 42 is rotatably connected with the box body 1, a gearbox 43 is arranged at the rear end of the third turbine shaft 42, an output shaft 44 is arranged at the rear end of the gearbox 43, the output shaft 44 is rotatably connected with the box body 1, and the rear end wall of the output shaft 44 is in power connection with a generator 45.
Beneficially, the water storage mechanism comprises a water storage tank 27 disposed on the bottom walls of the left and right water falling grooves 29 and 18, the water storage tank 27 is slidably connected to the box body 1, a pull ring 46 is fixedly connected to the rear end wall of the water storage tank 27, a water storage chamber 26 is disposed in the water storage tank 27, a top wall of the water storage chamber 26 is provided with a left water falling hole 28 located on the lower side of the left water falling hole 28 and opening upwards, and a top wall of the water storage chamber 26 is provided with a right water falling hole 19 located on the lower side of the right water falling groove 18.
In an initial state, the first spring 10, the second spring 12, the third spring 22, the torsion spring 51, the fourth spring 47, the fifth spring 60, the sixth spring 67 and the seventh spring 71 are all in a normal tension state;
sequence of mechanical actions of the whole device:
1. when the precipitation reaches the opening value range, the rainwater impacts the second turbine 56 to rotate, so that the second turbine shaft 33 rotates, the first gear 32 rotates, the winder 34 rotates, the top pull rope 3 pulls the top shading block 8 to move leftwards, and the rainwater falls into the right water falling groove 18;
2. rainwater flows into a cavity formed by the water storage ring 30 and the water storage rotating block 40, the accumulated water quantity continuously rises, when the power generation degree is reached, the rear side float 53 moves upwards, so that the rotating rod 52 rotates, the front side float 53 moves downwards to be contacted with the first inclined block 58, the first inclined block 58 moves downwards, the second inclined block 65 moves leftwards, the push block 70 moves upwards, the water storage rotating block 40 rotates around the first rotating shaft 39, the right end of the water storage rotating block 40 moves downwards, accumulated water is made to be flushed to the third turbine 41, the third turbine 41 rotates, the third turbine shaft 42 rotates, the output shaft 44 rotates, and hydroelectric power is generated, and the water finally flows into the water storage cavity 26 to be stored;
3. when the precipitation is excessive, the first turbine 16 rotates, so that the first turbine shaft 17 rotates, so that the centrifugal block 24 rotates, the speed required by the centrifugation is reached, the push rod 15 pushes the diversion block 14 to move upwards, so that water flows into the cavity formed by the left water storage ring 30 and the water storage rotating block 40 from the right side along the second chute 20, the chute 21 and the first chute 13, the accumulated water continuously rises, the rear float 53 moves upwards when the power generation degree is reached, so that the rotating rod 52 rotates, so that the front float 53 moves downwards to be in contact with the first inclined block 58 and the first inclined block 58 moves downwards, so that the second inclined block 65 moves leftwards, so that the push block 70 moves upwards, so that the water storage rotating block 40 rotates around the first rotating shaft 39, so that the right end of the water storage rotating block 40 moves downwards, so that the accumulated water is pushed to the third turbine 41, so that the third turbine 41 rotates, thereby rotating the third turbine shaft 42, thereby rotating the output shaft 44, thereby generating electricity by water power, and finally flowing water into the water storage cavity 26 for storage;
4. when the device needs to reset, the rainfall stops, the second turbine 56 stops rotating, the first sliding block 9 and the top shielding block 8 move rightwards under the reset action of the first spring 10 to shield the top wall of the right water dropping groove 18, so that all moving parts stop moving, the pull ring 46 is pulled to pour out the water stored in the water storage cavity 26, then the water storage tank 27 slides to the original position, and the device finishes resetting.
The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.
Claims (6)
1. The utility model provides a hydroelectric generation device according to precipitation regulation, includes the box, its characterized in that: the top wall of the box body is provided with an upward chute with an upward opening, the bottom wall of the upward chute is provided with a turbine groove with an upward opening, the top wall of the box body is provided with an opening mechanism, the top wall of the right end of the box body is provided with a right water falling groove with an upward opening, the left end wall of the right water falling groove is fixedly provided with a first chute with a leftward opening, the left and right end walls of the first chute are fixedly connected with inclined pipes which are arranged in bilateral symmetry, a shunting mechanism is arranged at the position of the first chute, one end of each inclined pipe, far away from the first chute, is fixedly connected with a water storage ring, a second chute which is communicated with the left and right is arranged on the end wall of the right water passing pipe, the second chute is communicated with the inclined pipes, the bottom end of the water storage ring is slidably connected with a water storage rotating block, the left and right ends of the water storage, the left end wall of the first chute is provided with a left water falling groove with a downward opening, the left side of the left end wall of the water storage ring is fixedly connected with the left water falling groove, the left side and the right side of the lower side of the water storage ring are bilaterally symmetrically provided with power generation mechanisms, and the bottom walls of the right water falling groove and the left water falling groove are provided with water storage mechanisms.
2. A hydro-power generation device that adjusts according to precipitation as claimed in claim 1, wherein: the opening mechanism comprises a second turbine arranged in a turbine groove, a left water pipe with an upward opening is arranged on the bottom wall of the turbine groove, a right water pipe with a rightward opening is arranged at the bottom end of the right end wall of the left water pipe, the right end wall of the right water pipe is fixedly connected with a water storage ring and communicated with the interior of the water storage ring, the right end wall of the second turbine is fixedly connected with a second turbine shaft, the second turbine shaft is rotatably connected with a box body, the right end of the second turbine shaft is fixedly connected with a first gear, a winder is fixedly arranged at the right end of the first gear, the winder and the first gear are positioned in a winder cavity, a top rope is wound on the winder, a rope pulling groove with an upward opening is arranged on the top wall of the winder cavity, a first rotating wheel is fixedly connected between the front end wall and the rear end wall of the rope pulling groove, a top block is fixedly arranged on the top wall of the, fixedly connected with second runner between the end wall around the second spout left end, the second spout shelters from a piece sliding connection with the top, the top stay cord other end is walked around first runner and second runner in proper order and is sheltered from a piece left end wall fixed connection with the top, second spout roof is provided with the first spout that the opening is decurrent, the top is sheltered from a fixed first slider that is provided with of piece roof, first slider is located first spout and rather than sliding connection, through first spring coupling between first slider right-hand member wall and the first spout right-hand member wall.
3. A hydro-power generation device that adjusts according to precipitation as claimed in claim 1, wherein: the shunting mechanism comprises a third chute arranged on the top wall of the first chute and with a downward opening, the third chute is in sliding connection with a shunting stop block, the top wall of the shunting stop block is connected with the top wall of the third chute through a second spring, a centrifugal block cavity positioned on the lower side of the first chute is arranged below the shunting stop block, a centrifugal block is arranged in the centrifugal block cavity, a centrifugal cavity is arranged in the centrifugal block, the centrifugal block is in sliding connection with a push rod which is uniformly arranged, the inner end of the push rod is positioned in the centrifugal cavity, the push rod is connected with the push rod through a third spring, the upper end of the push rod is positioned below the bottom wall of the shunting stop block, the centrifugal block is fixedly connected with a first turbine shaft, the first turbine shaft is connected with a box body in a rotating mode, and the right end of the first turbine shaft is.
4. A hydro-power generation device that adjusts according to precipitation as claimed in claim 1, wherein: the water-pouring mechanism comprises an upper rotating groove which is arranged at the top end of the front side of the water storage ring and has an upward opening, a second rotating shaft is fixedly connected between the left end wall and the right end wall of the upper rotating groove, the second rotating shaft is connected with the upper rotating groove through a torsion spring, the second rotating shaft is rotatably connected with a rotating rod, floats are symmetrically and fixedly arranged at the front end and the rear end of the rotating rod in a front-back manner, the floats at the front side are positioned in a transfer groove with a backward opening, a first inclined block groove with an upward opening is arranged at the bottom wall of the transfer groove, the first inclined block groove is slidably connected with a first inclined block, the top end of the first inclined block is positioned in the transfer groove, a second sliding block is fixedly arranged at the right end wall of the first inclined block, the second sliding block is positioned in a fourth sliding groove and is slidably connected with the fourth sliding groove, the bottom wall of the second sliding block is connected with the fourth sliding groove through a fifth spring, the front end of the rotating block is positioned, the water storage rotating block is rotatably connected with the first rotating shaft, the bottom wall of the front side of the water storage rotating block is connected with the bottom wall of the lower rotating groove through a fourth spring, a fifth chute which is communicated up and down is arranged at the left part of the water storage rotating block, the fifth chute is slidably connected with the first inclined block, the bottom wall of the first inclined block is slidably connected with the second inclined block, the second inclined block is positioned in the second inclined block groove with a right opening and is slidably connected with the second inclined block groove, a third sliding block is fixedly arranged on the bottom wall of the second inclined block, the third sliding block is positioned in the sixth chute and is slidably connected with the sixth chute, and a sixth spring is arranged between the left end wall of the third sliding block and the left end wall of the sixth chute; and the second oblique block left end wall is connected with the push block in a sliding manner, the push block top wall is contacted with the water storage rotating block bottom wall, the spring block is fixedly arranged on the push block left end wall, and the spring block bottom wall is connected with the lower rotating block bottom wall through a seventh spring.
5. A hydro-power generation device that adjusts according to precipitation as claimed in claim 1, wherein: the power generation mechanism is including setting up in the third turbine of retaining commentaries on classics piece downside, third turbine rear end wall and third turbine shaft fixed connection, the third turbine shaft rotates with the box to be connected, third turbine shaft rear end is provided with the gearbox, the gearbox rear end is provided with the output shaft, the output shaft rotates with the box to be connected, output shaft rear end wall is connected with generator power.
6. A hydro-power generation device that adjusts according to precipitation as claimed in claim 1, wherein: the water storage mechanism comprises a water storage tank arranged on the bottom wall of the left water falling groove and the right water falling groove, the water storage tank is connected with the tank body in a sliding mode, the rear end wall of the water storage tank is fixedly connected with a pull ring, a water storage cavity is arranged in the water storage tank, the top wall of the water storage cavity is provided with a left water falling opening which is located on the lower side of the left water falling opening and is provided with an upward opening, and the top wall of the water storage cavity is provided with a right water falling.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202010001315.3A CN110984353B (en) | 2020-01-02 | 2020-01-02 | Hydroelectric generation device adjusted according to precipitation |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202010001315.3A CN110984353B (en) | 2020-01-02 | 2020-01-02 | Hydroelectric generation device adjusted according to precipitation |
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| CN110984353A true CN110984353A (en) | 2020-04-10 |
| CN110984353B CN110984353B (en) | 2021-01-15 |
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| CN202010001315.3A Active CN110984353B (en) | 2020-01-02 | 2020-01-02 | Hydroelectric generation device adjusted according to precipitation |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
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