CN111577512A

CN111577512A - Spiral acceleration hydroelectric power generation equipment with heat dissipation function

Info

Publication number: CN111577512A
Application number: CN202010514939.5A
Authority: CN
Inventors: 王杰
Original assignee: Zhuji Luoxing New Energy Technology Co ltd
Current assignee: Zhuji Luoxing New Energy Technology Co ltd
Priority date: 2020-06-08
Filing date: 2020-06-08
Publication date: 2020-08-25

Abstract

The invention discloses spiral acceleration hydroelectric power generation equipment with a heat dissipation function, which comprises a power generation cavity arranged in a machine body, wherein the right side of the power generation cavity is communicated with the outside of the machine body; the invention has simple and convenient operation and low manufacturing cost, water flow can be accelerated by the spiral piece and then pushes the impeller to drive the generator to start for generating electricity, the water flow can push the scraper blade to drive the fan blade to rotate, so that air in the power generation cavity flows to dissipate heat of the generator, and meanwhile, impurities filtered out by the first filter screen are scraped into the third guide groove by the scraper blade to prevent the first filter screen from being blocked.

Description

Spiral acceleration hydroelectric power generation equipment with heat dissipation function

Technical Field

The invention relates to the technical field of power generation equipment, in particular to spiral acceleration hydraulic power generation equipment with a heat dissipation function.

Background

The basic principle of hydroelectric power generation is that the potential energy of water is converted into the mechanical energy of a water wheel, and then the mechanical energy is used for driving a generator to obtain electric power, the generator can generate a large amount of heat during power generation, and because the hydroelectric generator is usually installed outdoors, impurities such as fallen leaves and dust are easy to accumulate in heat dissipation holes of the generator, and the impurities often block the heat dissipation holes to influence the discharge of the heat in the generator, so that the generator is damaged, and the service life of the generator is shortened.

Disclosure of Invention

The object of the present invention is to provide a spiral acceleration hydroelectric power plant with heat dissipation function, which overcomes the above-mentioned drawbacks of the prior art.

The spiral accelerating hydroelectric power generation equipment with the heat dissipation function comprises a machine body, wherein a power generation cavity is arranged in the machine body, the right side of the power generation cavity is communicated with the outside of the machine body, a power generator is fixedly arranged on the lower side wall of the power generation cavity, a planetary accelerating cavity is arranged on the lower side of the power generation cavity, a flow guide cavity is arranged on the lower side of the planetary accelerating cavity, the left side and the right side of the flow guide cavity are communicated with the outside of the machine body, an impeller cavity is arranged on the lower side of a scraper, a power generation device for driving the power generator to start to generate power is arranged in the impeller cavity, the power generation device comprises an impeller cavity, a flow guide cavity, a transmission cavity and a transmission shaft II which is rotatably arranged among the planetary accelerating cavities, impellers are fixedly arranged on the transmission shaft II in the impeller cavity, and spiral accelerating cavities are arranged on the, a first filter screen and a spiral blade are fixedly arranged on the inner wall of the spiral accelerating cavity in sequence from top to bottom, a first flow guide groove communicated with the impeller cavity is formed in the lower side wall of the spiral accelerating cavity, a second flow guide groove communicated with the outside of the machine body is formed in the lower side wall of the impeller cavity, a connecting plate is fixedly arranged on the second transmission shaft in the planet accelerating cavity, a gear ring is fixedly arranged on the upper side wall of the connecting plate, a first rotating shaft is symmetrically and rotatably arranged at the left and right positions of the upper side wall of the planet accelerating cavity, a first gear meshed with the gear ring is fixedly arranged on the rotating shaft, a third transmission shaft extending into the planet accelerating cavity is rotatably arranged on the lower side wall of the generator, and a second gear meshed with; after being filtered by the first filter screen, water flows downwards along the spiral plate in an accelerated manner and flows into the impeller cavity along the spiral plate, the impeller is pushed to drive the second transmission shaft to rotate, the second transmission shaft drives the connecting plate to rotate, the connecting plate drives the rotating shaft to rotate by being meshed with the first gear through the gear ring, and the rotating shaft drives the third transmission shaft to rotate by being meshed with the second gear through the first gear, so that the generator is started to generate electricity.

On the basis of the technical scheme, a first transmission cavity is arranged on the upper side of the power generation cavity, and a heat dissipation device for dissipating heat of the power generator is arranged in the power generation cavity.

On the basis of the technical scheme, the heat dissipation device comprises a transmission shaft IV which is rotatably arranged between the power generation cavity and the transmission cavity I, the tail ends of the four lower sides of the transmission shaft are fixedly provided with fan blades, the tail ends of the four upper sides of the transmission shaft are fixedly provided with a first belt wheel, a transmission shaft V is rotatably arranged between the first transmission cavity and the third transmission cavity, a belt wheel II is fixedly arranged at the tail end of the upper side of the transmission shaft V, a first belt is arranged between the second belt wheel and the first belt wheel in a transmission way, a third belt wheel is fixedly arranged at the tail end of the lower side of the fifth transmission shaft, a sleeve is rotatably arranged between the third transmission cavity and the second diversion cavity and sleeved on the second transmission shaft, a belt wheel IV and a belt wheel V are fixedly arranged on the sleeve in the transmission cavity III from top to bottom in sequence, a belt II is arranged between the belt wheel IV and the belt wheel III in a transmission way, the tail end of the lower side of the sleeve is fixedly provided with a scraper, and the lower side wall of the flow guide cavity is provided with a third flow guide groove.

On the basis of the technical scheme, a first guide groove is formed in the inner wall of the power generation cavity, a sliding plate is arranged in the first guide groove in a sliding mode, a first spring is fixedly arranged between the sliding plate and the left side wall of the first guide groove, a second filter screen is fixedly arranged on the sliding plate, a second transmission cavity is arranged on the right side of the planet acceleration cavity, and a dust removal device which drives the sliding plate to slide left and right along the first guide groove to remove dust adsorbed on the second filter screen is arranged in the second transmission cavity.

On the basis of the technical scheme, the dust removing device comprises a guide groove II which is formed in the upper side wall of the transmission cavity II and is communicated with the guide groove I, a guide groove III is formed in the lower side wall of the sliding plate, a limiting block is arranged in the guide groove III in a sliding manner, an auxiliary rod which penetrates through the guide groove and extends downwards into the transmission cavity II is fixedly arranged on the lower side wall of the limiting block, a transmission shaft I is rotatably arranged between the transmission cavity II and the transmission cavity III, a belt wheel VI is fixedly arranged at the tail end of the lower side of the transmission shaft I, a belt III is arranged between the belt wheel VI and the belt wheel V in a transmission manner, a connecting rod is fixedly arranged at the tail end of the upper side of the transmission shaft I, a fixing pin is fixedly arranged on the upper side wall of the connecting rod, a guide groove IV is symmetrically formed between the front wall and the rear wall of the, and a push block is fixedly arranged on the upper side wall of the sliding block.

The invention has the beneficial effects that: the invention has simple and convenient operation and low manufacturing cost, water flow can be accelerated by the spiral piece and then pushes the impeller to drive the generator to start for generating electricity, the water flow can push the scraper blade to drive the fan blade to rotate, so that air in the power generation cavity flows to dissipate heat of the generator, and meanwhile, impurities filtered out by the first filter screen are scraped into the third guide groove by the scraper blade to prevent the first filter screen from being blocked.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic structural front view of a spiral accelerating hydroelectric power generation device with heat dissipation function according to 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;

FIG. 5 is an enlarged partial view of the structure of FIG. 1 at D;

FIG. 6 is an enlarged schematic view of the planetary accelerating cavity of FIG. 1;

fig. 7 is an enlarged schematic view of the structure of three positions of the transmission cavity in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, 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 7, a spiral acceleration hydroelectric power generating apparatus with a heat dissipation function according to an embodiment of the present invention includes a machine body 10, a power generating cavity 16 is disposed in the machine body 10, the right side of the power generating cavity 16 is communicated with the outside of the machine body 10, a power generator 20 is fixedly mounted on the lower side wall of the power generating cavity 16, a planetary acceleration cavity 35 is disposed on the lower side of the power generating cavity 16, a diversion cavity 37 is disposed on the lower side of the planetary acceleration cavity 35, the left and right sides of the diversion cavity 37 are communicated with the outside of the machine body 10, an impeller cavity 39 is disposed on the lower side of the scraper 23, a power generating device 63 for driving the power generator 20 to start to generate power is disposed in the impeller cavity 39, the power generating device 63 includes the impeller cavity 39, the diversion cavity 37, the third transmission cavity 32 and a second transmission shaft 26 rotatably disposed between the planetary acceleration cavity 35, an impeller 27 is fixedly disposed on the, the lower side wall of the diversion cavity 37 is provided with spiral accelerating cavities 30 in an annular array with the power generation cavity 16 as the center, a first filter screen 31 and a spiral sheet 29 are fixedly arranged on the inner wall of the spiral accelerating cavity 30 from top to bottom in sequence, the lower side wall of the spiral accelerating cavity 30 is provided with a first diversion trench 28 communicated with the impeller cavity 39, the lower side wall of the impeller cavity 39 is provided with a second diversion trench 25 communicated with the outside of the machine body 10, a connecting plate 53 is fixedly arranged on the second transmission shaft 26 in the planetary accelerating cavity 35, a gear ring 57 is fixedly arranged on the upper side wall of the connecting plate 53, a rotating shaft 55 is symmetrically and rotatably arranged at the left and right positions of the upper side wall of the planetary accelerating cavity 35, a first gear 56 meshed with the gear ring 57 is fixedly arranged on the rotating shaft 55, a third transmission shaft 54 extending into the planetary acceleration cavity 35 is rotatably mounted on the lower side wall of the generator 20, and a second gear 58 meshed with the first gear 56 is fixedly arranged on the third transmission shaft 54; after being filtered by the first filter screen 31, the water flows downwards along the spiral piece 29 at an accelerated speed and flows into the impeller cavity 39 along the impeller 2, the second transmission shaft 26 is driven to rotate by pushing the impeller 27, the second transmission shaft 26 drives the connecting plate 53 to rotate, the connecting plate 53 is meshed with the first gear 56 through the gear ring 57 to drive the rotating shaft 55 to rotate, and the rotating shaft 55 is meshed with the second gear 58 through the first gear 56 to drive the third gear 54 to rotate, so that the generator 20 is started to generate electricity.

In addition, in one embodiment, a first transmission cavity 15 is arranged on the upper side of the power generation cavity 16, and a heat dissipation device 64 for dissipating heat of the power generator 20 is arranged in the power generation cavity 16.

In addition, in one embodiment, the heat dissipation device 64 includes a transmission shaft four 14 rotatably disposed between the power generation cavity 16 and the transmission cavity one 15, a fan blade 19 is fixedly disposed at a lower end of the transmission shaft four 14, a pulley one 13 is fixedly disposed at an upper end of the transmission shaft four 14, a transmission shaft five 34 is rotatably disposed between the transmission cavity one 15 and the transmission cavity three 32, a pulley two 11 is fixedly disposed at an upper end of the transmission shaft five 34, a belt first 12 is disposed between the pulley two 11 and the pulley one 13 in a transmission manner, a pulley three 33 is fixedly disposed at a lower end of the transmission shaft five 34, a sleeve 38 is rotatably disposed between the transmission cavity three 32 and the diversion cavity 37, the sleeve 38 is sleeved on the transmission shaft two 26, a pulley four 60 and a pulley five 61 are sequentially and fixedly disposed on the sleeve 38 from top to bottom in the transmission cavity three 32, a belt two 59 is disposed between the pulley four 60 and the pulley three 33 in a transmission manner, the tail end of the lower side of the sleeve 38 is fixedly provided with a scraper 23, and the lower side wall of the diversion cavity 37 is provided with a diversion trench III 24; rivers are through promoting scraper blade 23 drives sleeve 38 rotates, sleeve 38 passes through band pulley four 60 band pulley three 33 and belt two 59 drive transmission shaft five 34 rotate, transmission shaft five 34 passes through band pulley two 11 band pulley one 13 and belt one 12 drives transmission shaft four 14 rotates, transmission shaft four 14 drives flabellum 19 rotates, makes the interior air flow of electricity generation chamber 16 reduces the heat that generator 20 sent.

In addition, in one embodiment, a first guide groove 41 is formed in the inner wall of the power generation cavity 16, a sliding plate 17 is slidably disposed in the first guide groove 41, a first spring 40 is fixedly disposed between the sliding plate 17 and the left side wall of the first guide groove 41, a second filter screen 18 is fixedly disposed on the sliding plate 17, a second transmission cavity 36 is disposed on the right side of the planetary acceleration cavity 35, and a dust removing device 65 for driving the sliding plate 17 to slide left and right along the first guide groove 41 to remove dust adsorbed on the second filter screen 18 is disposed in the second transmission cavity 36.

In addition, in one embodiment, the dust removing device 65 includes a second guide groove 43 formed in the upper side wall of the second transmission cavity 36 and communicated with the first guide groove 41, a third guide groove 52 formed in the lower side wall of the sliding plate 17, a third limiting block 50 slidably disposed in the third guide groove 52, an auxiliary rod 49 extending downward into the second transmission cavity 36 through the second guide groove 43 and fixedly disposed on the lower side wall of the limiting block 50, a first transmission shaft 21 rotatably disposed between the second transmission cavity 36 and the third transmission cavity 32, a sixth pulley 22 fixedly disposed on the lower end of the first transmission shaft 21, a third belt 62 rotatably disposed between the sixth pulley 22 and the fifth pulley 61, a connecting rod 44 fixedly disposed on the upper end of the first transmission shaft 21, a fixing pin 45 fixedly disposed on the upper side wall of the connecting rod 44, a fourth guide groove 42 symmetrically formed between the front and rear walls of the second transmission cavity 36, and a sliding block 47 slidably disposed in the fourth guide groove 42, the lower side wall of the sliding block 47 is provided with a guide groove five 46 in sliding fit with the fixing pin 45, and the upper side wall of the sliding block 47 is fixedly provided with a pushing block 48; the sleeve 38 drives the transmission shaft one 21 to rotate through the pulley five 61, the pulley six 22 and the belt three 62, the transmission shaft one 21 drives the connecting rod 44 to rotate, the connecting rod 44 drives the sliding block 47 to slide leftwards along the guide groove four 42 through the fixed pin 45 and the guide groove five 46, the sliding block 47 drives the auxiliary rod 49 through the pushing block 48 to drive the sliding plate 17 to slide leftwards along the guide groove one 41, when the sliding plate 17 moves to the left limit position, the auxiliary rod 49 moves upwards along the guide groove three 52 and is separated from contact with the pushing block 48, so that the sliding plate 17 moves rightwards under the action of the spring one 40 and impacts on the right side wall of the guide groove one 41, and dust adsorbed on the filter screen two 18 is shaken off.

In the initial state, the first spring 40 and the second spring 51 are in a semi-compressed state, so that the sliding plate 17 is in contact with the right side wall of the first guide groove 41, and the stop block 50 is in contact with the lower side wall of the third guide groove 52.

When power generation is started, water flows into the spiral accelerating cavity 30 after being filtered by the first filter screen 31, and after the water flows are accelerated by the spiral sheet 29, the second transmission shaft 26 is driven to rotate by pushing the impeller 27, and the second transmission shaft 26 drives the generator 20 to operate through the power generation device 63 to generate power.

When heat dissipation is started, water flow drives the sleeve 38 to rotate by pushing the scraper 23, meanwhile, impurities filtered out by the first filter screen 31 are scraped into the third guide groove 24 by the scraper 23, so that the impurities continue to flow along the water washing direction, the sleeve 38 drives the fan blades 19 to rotate by the heat dissipation device 64, so that air in the power generation cavity 16 flows, heat dissipation is performed on the power generator 20, meanwhile, the sleeve 38 drives the sliding plate 17 to move leftwards by the dust removal device 65, and when the sliding plate 17 moves to the limit position, the sliding plate 17 quickly impacts against the right side wall of the first guide groove 41 under the action of the first spring 40, so that dust adsorbed on the second filter screen 18 is shaken off.

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 a spiral is hydroelectric power generation equipment with heat dissipation function with higher speed, includes the organism, its characterized in that: the generator is characterized in that a generating cavity is arranged in the generator body, the right side of the generating cavity is communicated with the outside of the generator body, a generator is fixedly arranged on the lower side wall of the generating cavity, a planet accelerating cavity is arranged on the lower side of the generating cavity, a flow guide cavity is arranged on the lower side of the planet accelerating cavity, the left side and the right side of the flow guide cavity are communicated with the outside of the generator body, an impeller cavity is arranged on the lower side of the scraper, a generating device for driving the generator to start to generate electricity is arranged in the impeller cavity, the generating device comprises the impeller cavity, the flow guide cavity, a transmission cavity III and a transmission shaft II which is rotatably arranged among the planet accelerating cavities, an impeller is fixedly arranged on the transmission shaft II in the impeller cavity, a spiral accelerating cavity is arranged on the lower side wall of the flow guide cavity by taking the generating cavity as a central annular array, a filter screen I and a spiral blade are sequentially arranged on the, a second diversion trench communicated with the outside of the machine body is formed in the lower side wall of the impeller cavity, a connecting plate is fixedly arranged on the second transmission shaft in the planetary acceleration cavity, a gear ring is fixedly arranged on the upper side wall of the connecting plate, rotating shafts are symmetrically and rotatably arranged on the left and right positions of the upper side wall of the planetary acceleration cavity, a first gear meshed with the gear ring is fixedly arranged on each rotating shaft, a third transmission shaft extending into the planetary acceleration cavity is rotatably arranged on the lower side wall of the generator, and a second gear meshed with the first gear is fixedly arranged on each third transmission shaft; after being filtered by the first filter screen, water flows downwards along the spiral plate in an accelerated manner and flows into the impeller cavity along the spiral plate, the impeller is pushed to drive the second transmission shaft to rotate, the second transmission shaft drives the connecting plate to rotate, the connecting plate drives the rotating shaft to rotate by being meshed with the first gear through the gear ring, and the rotating shaft drives the third transmission shaft to rotate by being meshed with the second gear through the first gear, so that the generator is started to generate electricity.

2. The spiral accelerating hydropower device with the heat dissipation function of claim 1, wherein: the upper side of the power generation cavity is provided with a first transmission cavity, and a heat dissipation device for dissipating heat of the power generator is arranged in the power generation cavity.

3. The spiral accelerating hydropower device with the heat dissipation function of claim 2, characterized in that: the heat dissipation device comprises a transmission shaft IV which is rotatably arranged between the power generation cavity and the transmission cavity I, the tail ends of the four lower sides of the transmission shaft are fixedly provided with fan blades, the tail ends of the four upper sides of the transmission shaft are fixedly provided with a first belt wheel, a transmission shaft V is rotatably arranged between the first transmission cavity and the third transmission cavity, a belt wheel II is fixedly arranged at the tail end of the upper side of the transmission shaft V, a first belt is arranged between the second belt wheel and the first belt wheel in a transmission way, a third belt wheel is fixedly arranged at the tail end of the lower side of the fifth transmission shaft, a sleeve is rotatably arranged between the third transmission cavity and the second diversion cavity and sleeved on the second transmission shaft, a belt wheel IV and a belt wheel V are fixedly arranged on the sleeve in the transmission cavity III from top to bottom in sequence, a belt II is arranged between the belt wheel IV and the belt wheel III in a transmission way, the tail end of the lower side of the sleeve is fixedly provided with a scraper, and the lower side wall of the flow guide cavity is provided with a third flow guide groove.

4. The spiral accelerating hydropower device with the heat dissipation function of claim 1, wherein: the power generation device is characterized in that a first guide groove is formed in the inner wall of the power generation cavity, a sliding plate is arranged in the first guide groove in a sliding mode, a first spring is fixedly arranged between the sliding plate and the left side wall of the first guide groove, a second filter screen is fixedly arranged on the sliding plate, a second transmission cavity is arranged on the right side of the planet acceleration cavity, and a dust removal device which drives the sliding plate to slide left and right along the first guide groove to remove dust adsorbed on the second filter screen is arranged in the second transmission cavity.

5. The spiral accelerating hydropower device with the heat dissipation function of claim 4, wherein: the dust removing device comprises a guide groove II which is formed in the upper side wall of the transmission cavity II and is communicated with the guide groove I, a guide groove III is formed in the lower side wall of the sliding plate, a limiting block is arranged in the guide groove III in a sliding mode, an auxiliary rod which penetrates through the guide groove and extends downwards into the transmission cavity II is fixedly arranged on the lower side wall of the limiting block, a transmission shaft I is rotatably arranged between the transmission cavity II and the transmission cavity III, a belt wheel III is fixedly arranged at the tail end of the lower side of the transmission shaft I, a belt III is arranged between the belt wheel III and the belt wheel V in a transmission mode, a connecting rod is fixedly arranged at the tail end of the upper side of the transmission shaft I, a fixing pin is fixedly arranged on the upper side wall of the connecting rod, a guide groove IV is symmetrically formed between the front wall and the rear wall of the transmission, and a push block is fixedly arranged on the upper side wall of the sliding block.