CN114703815A

CN114703815A - Solar photovoltaic power generation concealed pipe drainage equipment

Info

Publication number: CN114703815A
Application number: CN202210269769.8A
Authority: CN
Inventors: 刘洪光; 杨昌昆; 龚萍; 李鹏飞; 孔媛; 孟强; 吴啸竹; 吴怀硕; 李玉芳; 王春霞
Original assignee: Shihezi University
Current assignee: Shihezi University
Priority date: 2022-03-18
Filing date: 2022-03-18
Publication date: 2022-07-05

Abstract

The invention relates to drainage equipment, in particular to solar photovoltaic power generation concealed pipe drainage equipment. The invention aims to provide solar photovoltaic power generation concealed pipe drainage equipment which has a water electrolysis function and can convert solar energy into electric energy. The invention provides solar photovoltaic power generation concealed pipe drainage equipment which comprises an electrolytic cell, supporting legs, valves, a top plate, a partition plate and the like, wherein the supporting legs are arranged on the front side and the rear side of the bottom of the electrolytic cell, the valves are arranged on the right parts of the front side and the rear side of the electrolytic cell, the top plate is arranged on the upper portion of the inner side of the electrolytic cell, a rectangular hole is formed in the left portion of the front side of the top plate, the partition plate is arranged in the middle of the bottom of the top plate, and the partition plate is connected with the inner wall of the electrolytic cell. According to the invention, after the clean water flows into the rear part of the inner side of the electrolytic cell, the positive electrode and the first negative electrode are electrified, so that the clean water at the rear part of the inner side of the electrolytic cell can be electrolyzed by the positive electrode and the first negative electrode, and the pollution to the environment can be reduced by the discharged clean water.

Description

Solar photovoltaic power generation hidden pipe drainage equipment

Technical Field

The invention relates to drainage equipment, in particular to solar photovoltaic power generation concealed pipe drainage equipment.

Background

The concealed pipe drainage technology is a main technical means for improving soil salinization at present, mainly uses soil salt leaching as a main technology, buries a water-permeable pipeline at a proper position underground to control underground water level and improve soil physicochemical property, and effectively reduces the influence of field engineering on planting area, thereby achieving the effect of promoting agricultural yield increase, and the water and salt regulation and control and concealed pipe drainage technology is an important development direction for saline-alkali soil treatment in the future. However, in actual farmland engineering, high saline-alkali water discharged by a concealed conduit is directly discharged without treatment, secondary pollution is easily caused, safety of farmland underground water and soil near drainage is seriously threatened, water resources are wasted, although the high saline-alkali water treated by the current electrolytic method has the advantages of high efficiency and stability, the development of the electrolytic water in China is not ideal due to consideration of electric energy resources, the light energy resources in just western regions are abundant, and the light energy power generation can provide electric energy resources for concealed conduit drainage and electrolysis of farmlands in the western regions, so that the energy utilization is achieved.

Therefore, in order to solve the problems, the solar photovoltaic power generation concealed conduit drainage equipment which has the function of electrolyzing water and can convert solar energy into electric energy is provided.

Disclosure of Invention

The invention aims to overcome the defects that the discharged high-salt alkaline water easily causes secondary pollution to the environment and a large amount of electric energy is consumed by electrolyzed water when people drain water in a concealed conduit at present, and people are difficult to implement in a large amount.

The invention is realized by the following technical approaches:

a solar photovoltaic power generation concealed pipe drainage device comprises an electrolytic cell, supporting legs, valves, a top plate, a partition plate, positive electrodes, first negative electrodes, second negative electrodes, a water inlet pipe, a water inlet valve, an air guide machine, a storage battery, a power storage mechanism, an adjusting mechanism, a settling mechanism and a decontamination mechanism, wherein the supporting legs are arranged on the front side and the rear side of the bottom of the electrolytic cell, the valves are arranged on the right parts of the front side and the rear side of the electrolytic cell, the top plate is arranged on the upper part of the inner side of the electrolytic cell, a rectangular hole is formed in the left part of the front side of the top plate, the partition plate is arranged in the middle of the bottom of the top plate and connected with the inner wall of the electrolytic cell, the positive electrodes are arranged on the left part of the rear side of the electrolytic cell, the first negative electrodes for electrolyzing water are arranged on the right part of the rear side of the partition plate, the second negative electrodes are arranged on the left side and the right side of the front side of the inner side of the electrolytic cell, the water inlet valve is connected with the water inlet pipe in the middle of the left side of the upper side of the inner side of the electrolytic cell, the rear side of the water inlet valve is rotatably connected with the water inlet pipe, the middle part of the right side of the upper part of the top plate is provided with the air guide machine, the upper part of the right side of the electrolytic cell is provided with a storage battery, the upper part of the electrolytic cell is provided with an electric power storage mechanism for converting solar energy into electric energy, the electric power storage mechanism is provided with an adjusting mechanism for adjusting the orientation, the lower part of the left side of the electrolytic cell is provided with a settling mechanism for settling clean water, and the settling mechanism is provided with a dirt removing mechanism for cleaning sediments.

In one embodiment, the power storage mechanism comprises a mounting frame, a first photovoltaic plate, a connecting frame and a second photovoltaic plate, wherein the mounting frame is arranged on the upper portion of the front side and the upper portion of the rear side of the electrolytic cell, the first photovoltaic plate is arranged on the upper portion of the mounting frame in an homorotation mode, the first photovoltaic plate is electrically connected with the storage battery, the connecting frame is arranged on the left side and the right side of the top of the electrolytic cell, the second photovoltaic plate is arranged on the upper portion of the connecting frame in an homorotation mode, and the second photovoltaic plate is electrically connected with the storage battery.

In one embodiment, the adjusting mechanism comprises a shaft sleeve, a first transmission shaft, a first screw rod, a first threaded pipe, a bevel gear, a second screw rod, a second threaded pipe, a chain wheel and a chain belt, wherein the shaft sleeve is arranged in the middle of the upper side of the connecting frame on the right side, the first transmission shaft is slidably arranged on the lower side of the shaft sleeve, the first screw rod is rotatably arranged on the upper side of the middle of the inner side of the first photovoltaic panel, the first threaded pipe is arranged in a threaded manner between the inner sides of the first screw rod, the bevel gear is arranged on the front side of the first threaded pipe and the left side of the first transmission shaft, the bevel gears are meshed with each other, the second screw rod is rotatably arranged on the upper side of the middle of the inner side of the second photovoltaic panel, the second threaded pipe is arranged in a threaded manner between the inner sides of the second screw rod, chain wheels are arranged on the right side of the second threaded pipe and the left side of the first transmission shaft, and the chain belt is wound between the chain wheels.

In one embodiment, the sedimentation mechanism comprises a sedimentation tank, a support frame, a switching frame, a water outlet valve and a transverse plate, the switching frame is arranged on the lower portion of the left side of the electrolytic tank, the support frame is arranged on the left side of the switching frame, the sedimentation tank is arranged on the top of the support frame, the water inlet pipe is communicated with the sedimentation tank, the water outlet valve is arranged on the lower side of the middle of the left side of the sedimentation tank, and the transverse plate is arranged between the middle portions of the front side and the rear side of the top of the sedimentation tank.

In one embodiment, the decontamination mechanism comprises a scraper, a filter screen, connecting rods, connecting sleeves, guide rods, compression springs and guide rails, the scraper is arranged on the right side of the inner bottom of the sedimentation tank in a sliding manner, the filter screen is arranged in the middle of the scraper, the connecting rods are arranged on the front side and the rear side of the left side of the scraper, the connecting sleeves are arranged between the tops of the connecting rods, the guide rods are arranged on the front side and the rear side of the inner side of the connecting sleeves in a sliding manner, the compression springs are arranged between the inner sides of the guide rods, the guide rails are arranged on the upper portion of the inner side of the sedimentation tank, and the outer sides of the guide rods are in contact with the tops of the guide rails.

In one embodiment, the automatic feeding device also comprises a feeding mechanism for automatically feeding sodium carbonate, the feeding mechanism comprises a rotating shaft, a circular material frame, a baffle plate, a hopper, a baffle cover, a second transmission shaft, a first gear, a second gear, a floating plate, a transmission wheel and a transmission belt, the circular material frame is arranged on the front side and the rear side of the upper part of the transverse plate, the rotating shaft is rotatably arranged between the middle parts of the circular material frames, the baffle plates are arranged on the front side and the rear side of the rotating shaft respectively, the baffle plates are positioned in the circular material frame on the same side, the hopper is arranged between the tops of the circular material frames, the baffle covers are rotatably arranged on the front side and the rear side of the upper part of the hopper, the second transmission shaft is rotatably arranged on the front side and the rear side of the upper part of the transverse plate, the second transmission shaft is positioned on the outer side of the circular material frame, the first gear is positioned on the outer side of the baffle plate, and the inner side of the second transmission shaft is provided with a second gear, the second gear all meshes with the first gear of homonymy, and the equal rotary type in upside middle part of both sides is equipped with the kickboard around the sedimentation tank, and the kickboard outside all is equipped with the drive wheel with the second transmission shaft outside, all around having the drive belt between two drive wheels of same vertical direction.

In one embodiment, the automatic sedimentation tank further comprises a driving mechanism used for enabling the connecting sleeve to automatically move, the driving mechanism comprises a bottom plate, a speed reducing motor, a spiral shaft and a spiral sleeve, the bottom plate is arranged on the upper portion of the left side of the sedimentation tank, the speed reducing motor is arranged on the top of the bottom plate, the spiral shaft is arranged on an output shaft of the speed reducing motor, the right side of the spiral shaft is rotatably connected with the sedimentation tank, the spiral sleeve is arranged on the right side of the spiral shaft in a threaded mode, and the lower portion of the spiral sleeve is connected with the connecting sleeve.

In one embodiment, the alkali feeding device further comprises a material pouring mechanism for feeding alkali, the material pouring mechanism comprises a box body, a sliding cover, an L-shaped sliding plate, a placing plate, a shifting wheel, a pull rod and a reset spring, the box body is arranged on the left portion of the front side of the top plate, the sliding cover is arranged on the upper portion of the inner side of the box body in a sliding mode, the L-shaped sliding plate is arranged on the left portion of the lower portion of the inner side of the box body in a sliding mode, the L-shaped sliding plate blocks the left side of the bottom of the box body, the placing plate is arranged on the lower portion of the inner side of the box body in a rotating mode, the shifting wheel is arranged in the middle of the front side and the rear side of the placing plate, the pull rod is arranged on the upper portions of the front side and the rear side of the L-shaped sliding plate, the pull rod right side is in contact with the shifting wheel on the same side, and the reset spring is arranged between the front and rear sides of the left portion of the bottom of the placing plate and the inner bottom of the box body.

In one embodiment, the automatic alkali feeding device further comprises a curved bar for automatically feeding alkali, a guide frame, a push wheel, a reset rod and a conical block, the curved bar is arranged on the lower side of the middle of the left side of the L-shaped sliding plate in a sliding mode, the guide frame is arranged on the front portion of the upper side of the left portion of the inner side of the electrolytic cell, the lower side of the curved bar penetrates through the guide frame, the left side of the upper portion of the curved bar is in contact with the connecting sleeve, the push wheel is arranged on the front side of the upper portion of the right side of the sedimentation tank in a rotating mode, the middle of the upper side of the curved bar is in contact with the push wheel, the reset rod is arranged on the left side of the upper portion of the curved bar and is in contact with the connecting sleeve, the conical block is arranged on the right portion of the upper side of the curved bar, and can be in contact with the push wheel when the conical block moves leftwards.

The invention provides solar photovoltaic power generation concealed pipe drainage equipment, which has the advantages that:

1. according to the invention, under the action of the first photovoltaic panel and the second photovoltaic panel, solar energy can be converted into electric energy to be stored in the storage battery, so that people can conveniently electrolyze water for drainage of the concealed pipe.

2. According to the invention, after the clean water flows into the rear part of the inner side of the electrolytic cell, the positive electrode and the first negative electrode are electrified, so that the clean water at the rear part of the inner side of the electrolytic cell can be electrolyzed by the positive electrode and the first negative electrode, and the pollution to the environment can be reduced by the discharged clean water.

3. According to the invention, the first transmission shaft is rotated forward and backward, so that the orientation angles of the first photovoltaic panel and the second photovoltaic panel can be adjusted at the same time, and sunlight can be better irradiated on the first photovoltaic panel and the second photovoltaic panel.

4. According to the automatic sodium carbonate feeding device, sodium carbonate is added into the hopper, and the sodium carbonate on the material blocking plate can automatically fall into the sedimentation tank through the circular material frame under the matching of the floating plate, the driving wheel, the driving belt, the second transmission shaft, the second gear, the first gear, the rotating shaft and the material blocking plate, so that the manual automatic sodium carbonate feeding is replaced.

5. According to the invention, by starting the speed reducing motor, people can conveniently move the connecting sleeve, so that the manual operation of people is reduced.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the electricity storage mechanism according to the present invention.

Fig. 3 is a schematic perspective view of the adjusting mechanism of the present invention.

Fig. 4 is a schematic perspective view of the settling mechanism of the present invention.

Fig. 5 is a schematic perspective view of the decontamination mechanism of the present invention.

Fig. 6 is a schematic perspective view of the charging mechanism of the present invention.

Fig. 7 is a schematic perspective view of the driving mechanism of the present invention.

Fig. 8 is a schematic partial three-dimensional structure diagram of the material pouring mechanism of the present invention.

Fig. 9 is a partial perspective view of the present invention.

In the reference symbols: 1-electrolytic cell, 2-support leg, 3-valve, 4-top plate, 5-separator, 6-positive electrode, 7-first negative electrode, 8-second negative electrode, 9-water inlet pipe, 10-water inlet valve, 11-air guide machine, 12-accumulator, 20-electricity storage mechanism, 21-mounting rack, 22-first photovoltaic plate, 23-connecting rack, 24-second photovoltaic plate, 30-adjusting mechanism, 31-shaft sleeve, 32-first transmission shaft, 33-first screw rod, 34-first screwed pipe, 35-bevel gear, 36-second screw rod, 37-second screwed pipe, 38-chain wheel, 39-chain belt, 40-settling mechanism, 41-settling tank, 42-support rack, 43-adapter rack, 44-water outlet valve, 45-transverse plate, 50-decontamination mechanism, 51-scraper, 52-filter screen, 53-connecting rod, 54-connecting sleeve, 55-guide rod, 56-compression spring, 57-guide rail, 60-feeding mechanism, 61-rotating shaft, 62-round material frame, 63-striker plate, 64-hopper, 65-baffle cover, 66-second transmission shaft, 67-first gear, 68-second gear, 69-floating plate, 610-transmission wheel, 611-transmission belt, 70-driving mechanism, 71-bottom plate, 72-speed reducing motor, 73-screw shaft, 74-screw sleeve, 80-material pouring mechanism, 81-box, 82-sliding cover, 83-L-shaped sliding plate, 84-placing plate, 85-thumb wheel, 86-pull rod, 87-return spring, 91-curved rod, 92-guide frame, 93-push wheel, 94-return rod and 95-conical block.

Detailed Description

The invention is further explained by combining the drawings in the specification, and the embodiments of the invention are given by combining the drawings in the specification.

Example 1

A solar photovoltaic power generation concealed pipe drainage device comprises an electrolytic cell 1, supporting legs 2, a valve 3, a top plate 4, a partition plate 5, a positive electrode 6, a first negative electrode 7, a second negative electrode 8, a water inlet pipe 9, a water inlet valve 10, an air guide machine 11, a storage battery 12, an electric storage mechanism 20, an adjusting mechanism 30, a settling mechanism 40 and a decontamination mechanism 50, wherein the supporting legs 2 are welded on the front side and the rear side of the bottom of the electrolytic cell 1, the valves 3 are arranged on the right parts of the front side and the rear side of the electrolytic cell 1, the top plate 4 is arranged on the upper part of the inner side of the electrolytic cell 1, a rectangular hole is formed in the left part of the front side of the top plate 4, the partition plate 5 is arranged in the middle of the bottom of the top plate 4, the partition plate 5 is connected with the inner wall of the electrolytic cell 1, the positive electrode 6 is arranged on the left part of the rear side inside of the electrolytic cell 1, the first negative electrode 7 is arranged on the right part of the rear side of the partition plate 5, clean water in the electrolytic cell 1 can be electrolyzed by electrifying the positive electrode 6 and the first negative electrode 7, the left side and the right side of the front side in the electrolytic cell 1 are respectively provided with a second negative electrode 8, the middle of the upper side of the left part of the electrolytic cell 1 is connected with a water inlet pipe 9, the front part of the left side of the upper side in the electrolytic cell 1 is rotatably provided with a water inlet valve 10, the rear side of the water inlet valve 10 is rotatably connected with the water inlet pipe 9, the middle of the right side of the upper part of the top plate 4 is provided with an air guide machine 11, the upper part of the right side of the electrolytic cell 1 is provided with a storage battery 12, the upper part of the electrolytic cell 1 is provided with an electric power storage mechanism 20, the electric power storage mechanism 20 is provided with an adjusting mechanism 30, the lower part of the left side of the electrolytic cell 1 is provided with a sedimentation mechanism 40, and the sedimentation mechanism 40 is provided with a decontamination mechanism 50.

Electric power storage mechanism 20 is including mounting bracket 21, first photovoltaic board 22, link 23 and second photovoltaic board 24, refer to fig. 2 and show, mounting bracket 21 has all been welded on the upper portion of the front and back both sides of electrolytic cell 1, the equal rotary type in mounting bracket 21 upper portion is equipped with first photovoltaic board 22, first photovoltaic board 22 passes through electric connection with battery 12, the 1 top left and right sides of electrolytic cell all is equipped with link 23, the equal rotary type in link 23 upper portion is equipped with second photovoltaic board 24, under the effect of first photovoltaic board 22 and second photovoltaic board 24, can convert solar energy into the electric energy, second photovoltaic board 24 passes through electric connection with battery 12.

The adjusting mechanism 30 includes a shaft sleeve 31, a first transmission shaft 32, a first screw 33, a first threaded pipe 34, a bevel gear 35, a second screw 36, a second threaded pipe 37, a chain wheel 38 and a chain belt 39, referring to fig. 3, the shaft sleeve 31 is welded at the middle of the upper side of the right connecting frame 23, the first transmission shaft 32 is slidably disposed at the lower side of the shaft sleeve 31, the orientations of the first photovoltaic panel 22 and the second photovoltaic panel 24 can be adjusted simultaneously by rotating the first transmission shaft 32 forward and backward, the first screw 33 is rotatably disposed at the upper side of the middle of the inner side of the first photovoltaic panel 22, the first threaded pipe 34 is threadedly disposed between the inner sides of the first screw 33, the bevel gear 35 is disposed at the front side of the first threaded pipe 34 and the left side of the first transmission shaft 32, the bevel gears 35 are engaged with each other, the second screw 36 is rotatably disposed at the upper side of the middle of the inner side of the second photovoltaic panel 24, the second threaded pipe 37 is threadedly disposed between the inner sides of the second screw 36, the right side of the second threaded pipe 37 and the left side of the first transmission shaft 32 are both provided with chain wheels 38, and a chain belt 39 is wound between the chain wheels 38.

The settling mechanism 40 comprises a settling tank 41, a support frame 42, a switching frame 43, a water outlet valve 44 and a transverse plate 45, and is shown in fig. 4, wherein the switching frame 43 is welded on the lower portion of the left side of the electrolytic tank 1, the support frame 42 is arranged on the left side of the switching frame 43, the settling tank 41 is arranged on the top of the support frame 42, clear water can be settled in the settling tank 41 after being poured into the settling tank 41, the water inlet pipe 9 is communicated with the settling tank 41, the water outlet valve 44 is arranged on the lower side of the middle portion of the left side of the settling tank 41, and the transverse plate 45 is arranged between the middle portions of the front side and the rear side of the top of the settling tank 41.

The decontamination mechanism 50 comprises scraping plates 51, a filter screen 52, connecting rods 53, connecting sleeves 54, guide rods 55, compression springs 56 and guide rails 57, as shown in fig. 5, the scraping plates 51 are arranged on the right side of the bottom in the sedimentation tank 41 in a sliding manner, the sediments can be scraped out leftwards through the left movement of the scraping plates 51, so that the sediments can be cleaned, the filter screen 52 is arranged in the middle of the scraping plates 51, the connecting rods 53 are welded on the front side and the rear side of the left side of the scraping plates 51, the connecting sleeves 54 are arranged between the tops of the connecting rods 53, the guide rods 55 are arranged on the front side and the rear side of the inner side of the connecting sleeves 54 in a sliding manner, the compression springs 56 are arranged between the inner sides of the guide rods 55, the guide rails 57 are arranged on the upper portion of the inner side of the sedimentation tank 41, and the outer sides of the guide rods 55 are in contact with the tops of the guide rails 57.

When people need to use the solar photovoltaic power generation concealed pipe drainage equipment, firstly, the solar photovoltaic power generation concealed pipe drainage equipment is placed at a designated position, then the first transmission shaft 32 is rotated forwards and backwards, the bevel gear 35 drives the first threaded pipe 34 to rotate forwards and backwards, the first screw 33 moves outwards or inwards, the first screw 33 drives the first photovoltaic panel 22 to rotate forwards and backwards, the orientation angle of the first photovoltaic panel 22 is adjusted, meanwhile, the first transmission shaft 32 drives the second threaded pipe 37 to rotate forwards and backwards through the chain wheel 38 and the chain belt 39, the second screw 36 moves outwards or inwards, the second screw 36 drives the second photovoltaic panel 24 to rotate forwards and backwards, the orientation angle of the second photovoltaic panel 24 is adjusted, after the adjustment is completed, the first transmission shaft 32 is loosened, when sunlight irradiates on the first photovoltaic panel 22 and the second photovoltaic panel 24, the first photovoltaic panel 22 and the second photovoltaic panel 24 convert solar energy into electric energy to be stored in the storage battery 12, then the hidden pipe is drained and drained into the sedimentation tank 41, sodium carbonate is added into the sedimentation tank 41 to be mixed with clean water in the sedimentation tank 41, then the mixture is kept still for a period of time to precipitate the clean water in the sedimentation tank 41, after a period of time, the water inlet valve 10 is opened in a rotating mode, the clean water precipitated in the sedimentation tank 41 enters the water inlet pipe 9 through the filter screen 52, and then flows into the rear part of the inner side of the electrolytic tank 1 through the water inlet pipe 9, during the period, the filter screen 52 filters the precipitated clean water to ensure that impurities in the precipitated clean water are left on the filter screen 52, when all the clean water precipitated in the sedimentation tank 41 flows into the rear part of the inner side of the electrolytic tank 1, the water inlet valve 10 is closed in a reverse rotation mode, the water outlet valve 44 is opened, then the impurities on the filter screen 52 are cleaned, and the connecting sleeve 54 is pulled to move leftwards, thereby driving the guide rod 55, the connecting rod 53, the filter screen 52 and the scraper 51 to move leftwards, causing the scraper 51 to scrape the sediment at the bottom in the sedimentation tank 41 leftwards, when the connecting sleeve 54 moves to contact with the inner wall of the sedimentation tank 41, the sedimentation tank 41 will press the guide rod 55 to move inwards at this time, the compression spring 56 is compressed, the scraper 51 will push the sediment outwards through the outlet valve 44, then the connecting sleeve 54 is pulled to move rightwards and reset, thereby driving the guide rod 55, the connecting rod 53, the filter screen 52 and the scraper 51 to move rightwards and reset, when the guide rod 55 is separated from the sedimentation tank 41, the compression spring 56 is reset, the compression spring 56 drives the guide rod 55 to move outwards and reset, causing the guide rod 55 to contact with the sedimentation tank 41, then the outlet valve 44 is closed, then the alkali is added into the front part of the inner side of the electrolytic tank 1 through the rectangular hole, the rectangular hole is blocked by the article, then the positive electrode 6 and the first negative electrode 7 are electrified, the method comprises the steps of enabling a positive electrode 6 and a first negative electrode 7 to electrolyze clean water at the rear part of the inner side of an electrolytic cell 1 to generate a large amount of chlorine, after the clean water at the rear part of the inner side of the electrolytic cell 1 is electrolyzed, powering off the positive electrode 6 and the first negative electrode 7, starting an air guide machine 11, leading all the chlorine into the front part of the inner side of the electrolytic cell 1 by the air guide machine 11, then closing the air guide machine 11, powering on a second negative electrode 8, enabling the chlorine to react with alkali to generate disinfectant, powering off the second negative electrode 8 after the chlorine and the alkali completely react, then opening a valve 3, collecting the clean water and the disinfectant which are electrolyzed in the electrolytic cell 1, and after all the electrolyzed clean water and the disinfectant which are electrolyzed in the electrolytic cell 1 are collected, closing the valve 3, and taking away articles blocked on a rectangular hole.

Example 2

On the basis of embodiment 1, the feeding mechanism 60 further comprises a rotating shaft 61, a round material frame 62, a material blocking plate 63, a hopper 64, a blocking cover 65, a second transmission shaft 66, a first gear 67, a second gear 68, a floating plate 69, a transmission wheel 610 and a transmission belt 611, referring to fig. 1 and 6, the round material frame 62 is welded on the front side and the rear side of the upper portion of the transverse plate 45, the rotating shaft 61 is rotatably arranged between the middle portions of the round material frames 62, the material blocking plates 63 are arranged on the front side and the rear side of the rotating shaft 61, sodium carbonate can be automatically added into the sedimentation tank 41 through rotation of the material blocking plates 63, so that sodium carbonate can be automatically fed, the material blocking plates 63 are positioned inside the round material frames 62 on the same side, the hopper 64 is arranged between the top portions of the round material frames 62, the blocking covers 65 are rotatably arranged on the front side and the rear side of the upper portion of the hopper 64, the second transmission shaft 66 is rotatably arranged on the front side and the rear side of the upper portion of the transverse plate 45, second transmission shaft 66 is located the outside of circle material frame 62, both sides all are equipped with first gear 67 around the pivot 61, first gear 67 is located the outside of striker plate 63, second transmission shaft 66 inboard all is equipped with second gear 68, second gear 68 all meshes with the first gear 67 of homonymy, the equal rotary type in upside middle part of both sides is equipped with kickboard 69 around the sedimentation tank 41, the kickboard 69 outside all is equipped with drive wheel 610 with the second transmission shaft 66 outside, all around there being drive belt 611 between two drive wheels 610 of same vertical direction.

When people need to use the solar photovoltaic power generation concealed pipe drainage equipment, the blocking cover 65 can be rotated and opened, then sodium carbonate is added into the hopper 64, the sodium carbonate drops on the baffle plate 63 through the hopper 64, then the blocking cover 65 is reversely closed, after people discharge concealed pipe drainage into the sedimentation tank 41, the water level of clean water in the sedimentation tank 41 rises, when the clean water is in contact with the floating plate 69, the floating plate 69 can float on the water surface through the clean water, so that the floating plate 69 rotates, the floating plate 69 drives the second transmission shaft 66 and the second gear 68 to rotate through the transmission wheel 610 and the transmission belt 611, so as to drive the first gear 67, the rotating shaft 61 and the baffle plate 63 to rotate, so that the sodium carbonate on the baffle plate 63 drops in the sedimentation tank 41 through the round material frame 62, thereby replacing manual automatic sodium carbonate feeding, meanwhile, the baffle plate 63 blocks the bottom of the hopper 64, when the clean water in the sedimentation tank 41 enters the water inlet pipe 9, the water level of clear water can descend in the sedimentation tank 41, when kickboard 69 and clear water separate, under the effect of gravity, kickboard 69 can reverse and reset, thereby drive second transmission shaft 66 and the reversal of second gear 68 through drive wheel 610 and drive belt 611, and then drive first gear 67, pivot 61 and striker plate 63 reverse, make striker plate 63 no longer block hopper 64 bottom, thereby make the sodium carbonate in the hopper 64 drop on striker plate 63, thereby make things convenient for people to carry out the material loading to the sodium carbonate.

The sedimentation basin is characterized by further comprising a driving mechanism 70, wherein the driving mechanism 70 comprises a bottom plate 71, a speed reducing motor 72, a spiral shaft 73 and a spiral sleeve 74, as shown in fig. 1 and 7, the bottom plate 71 is arranged at the upper part of the left side of the sedimentation basin 41, the speed reducing motor 72 is bolted to the top of the bottom plate 71, the connecting sleeve 54 can automatically move through the opening of the speed reducing motor 72, the spiral shaft 73 is arranged on an output shaft of the speed reducing motor 72, the right side of the spiral shaft 73 is rotatably connected with the sedimentation basin 41, the spiral sleeve 74 is screwed to the right side of the spiral shaft 73, and the lower part of the spiral sleeve 74 is connected with the connecting sleeve 54.

When people need to pull the connecting sleeve 54 to move leftwards, the speed reducing motor 72 can be started, the output shaft of the speed reducing motor 72 is controlled to rotate forwards, so that the spiral shaft 73 is driven to rotate forwards, the spiral sleeve 74 is driven to move leftwards, the connecting sleeve 54 is driven to move leftwards instead of being manually pulled, when people need to pull the connecting sleeve 54 to move rightwards, the output shaft of the speed reducing motor 72 is controlled to rotate backwards, so that the spiral shaft 73 is driven to rotate backwards, the spiral sleeve 74 is driven to move rightwards to reset, the connecting sleeve 54 is driven to move rightwards to reset, and then the speed reducing motor 72 is closed.

The alkali-removing device is characterized by further comprising a material pouring mechanism 80, wherein the material pouring mechanism 80 comprises a box body 81, a sliding cover 82, an L-shaped sliding plate 83, a placing plate 84, a shifting wheel 85, a pull rod 86 and a return spring 87, as shown in fig. 1, 8 and 9, the box body 81 is welded at the left part of the front side of the top plate 4, people can pour alkali into the box body 81, so that alkali can be fed, the sliding cover 82 is arranged at the upper part of the inner side of the box body 81 in a sliding manner, the L-shaped sliding plate 83 is arranged at the left part of the lower side of the inner part of the box body 81 in a sliding manner, the L-shaped sliding plate 83 blocks the left side of the bottom of the box body 81, the placing plate 84 is arranged at the lower part of the inner side in a rotating manner, the shifting wheels 85 are arranged at the middle parts of the front side and the rear side of the placing plate 84, the pull rods 86 are arranged at the upper parts of the front side and the rear side of the L-shaped sliding plate 83, the right side of the pull rods 86 are in contact with the shifting wheel 85 at the same side of the same side, and the return spring 87 is arranged between the front side and the front side of the bottom of the box body 81.

The alkali-removing device further comprises a curved bar 91, a guide frame 92, a push wheel 93, a reset bar 94 and a conical block 95, as shown in fig. 9, the curved bar 91 is arranged on the lower side of the middle portion of the left side of the L-shaped sliding plate 83 in a sliding mode, the curved bar 91 moves leftwards, the placing plate 84 can incline, alkali can automatically slide to the front portion of the inner side of the electrolytic cell 1 through the placing plate 84, the guide frame 92 is welded on the front portion of the upper side of the left portion of the inner side of the electrolytic cell 1, the lower side of the curved bar 91 penetrates through the guide frame 92, the left side of the upper portion of the curved bar 91 is in contact with the connecting sleeve 54, the push wheel 93 is arranged on the front side of the upper portion of the right side of the sedimentation tank 41 in a rotating mode, the middle portion of the upper side of the curved bar 91 is in contact with the push wheel 93, the reset bar 94 is arranged on the left side of the upper portion of the curved bar 91, the reset bar 94 is in contact with the connecting sleeve 54, the conical block 95 is arranged on the right portion of the upper side of the curved bar 91, and the conical block 95 can be in contact with the push wheel 93 when moving leftwards.

In the initial state, the return spring 87 is in a stretching state, when people need to use the solar photovoltaic power generation concealed conduit drainage device, the sliding cover 82 can be pulled to move rightwards to be opened, then alkali is poured into the box body 81 to drop on the placing plate 84, the sliding cover 82 is pulled to move leftwards to be closed, when the connecting sleeve 54 moves leftwards, the connecting sleeve 54 drives the curved rod 91 to move leftwards, so that the return rod 94, the conical block 95, the L-shaped sliding plate 83 and the pull rod 86 are driven to move leftwards, the L-shaped sliding plate 83 is not blocked on the left side of the bottom of the box body 81, when the pull rod 86 releases the shifting wheel 85, the return spring 87 restores the original shape, the return spring 87 drives the placing plate 84 and the shifting wheel 85 to rotate, the placing plate 84 is inclined, so that the alkali slides into the rectangular hole through the placing plate 84 and then drops into the front part of the inner side of the electrolytic cell 1 through the rectangular hole, and further replaces manual work to automatically load the alkali, when the cone block 95 contacts with the push wheel 93, the push wheel 93 presses the cone block 95 to move upwards, so as to drive the curved rod 91 and the reset rod 94 to move upwards, so that the curved rod 91 is separated from the connecting sleeve 54, so that the curved rod 91, the cone block 95, the L-shaped sliding plate 83 and the pull rod 86 stop moving, when the connecting sleeve 54 continues to move leftwards, the connecting sleeve 54 is separated from the reset rod 94, when the connecting sleeve 54 moves rightwards and resets, the connecting sleeve 54 contacts with the reset rod 94, at the same time, the connecting sleeve 54 drives the reset rod 94 to move rightwards and reset, so as to drive the curved rod 91, the cone block 95, the L-shaped sliding plate 83 and the pull rod 86 to move rightwards and reset, so that the L-shaped sliding plate 83 blocks the left side of the bottom of the box body 81 again, so that the pull rod 86 presses the dial wheel 85 to reset in a reverse direction, so as to drive the placing plate 84 to reset in a reverse direction, the reset spring 87 stretches, and when the cone block 95 is separated from the push wheel 93, under the action of gravity, the cone block 95 and the push wheel 93, the cone block 95 and the curved rod 91 move downwards and reset, the curved lever 91 is brought into contact with the coupling sleeve 54, and when the coupling sleeve 54 stops moving, the reset lever 94, the curved lever 91, the tapered block 95, the L-shaped slide plate 83 and the pull rod 86 stop moving.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention.

Claims

1. A solar photovoltaic power generation concealed conduit drainage device comprises an electrolytic cell (1), supporting legs (2), valves (3), a top plate (4), a partition plate (5), positive electrodes (6), first negative electrodes (7), second negative electrodes (8), a water inlet pipe (9), a water inlet valve (10), a gas guide machine (11) and a storage battery (12), wherein the supporting legs (2) are arranged on the front side and the rear side of the bottom of the electrolytic cell (1), the valves (3) are arranged on the right portions of the front side and the rear side of the electrolytic cell (1), the top plate (4) is arranged on the upper portion of the inner side of the electrolytic cell (1), a rectangular hole is formed in the left portion of the front side of the top portion of the top plate (4), the partition plate (5) is arranged in the middle of the bottom of the top plate (4), the partition plate (5) is connected with the inner wall of the electrolytic cell (1), the positive electrodes (6) are arranged on the left portion of the rear side of the inside of the electrolytic cell (1), the first negative electrodes (7) for electrolyzing water are arranged on the right portion of the rear side of the partition plate (5), the electrolytic cell is characterized by further comprising a power storage mechanism (20), an adjusting mechanism (30), a sedimentation mechanism (40) and a decontamination mechanism (50), wherein the power storage mechanism (20) for converting solar energy into electric energy is arranged at the upper part of the electrolytic cell (1), the adjusting mechanism (30) for adjusting the orientation is arranged on the power storage mechanism (20), the sedimentation mechanism (40) for precipitating clean water is arranged at the lower part of the left side of the electrolytic cell (1), the sedimentation mechanism (40) is provided with a decontamination mechanism (50) for cleaning sediment.

2. The solar photovoltaic power generation concealed conduit drainage equipment according to claim 1, wherein the power storage mechanism (20) comprises a mounting frame (21), a first photovoltaic plate (22), a connecting frame (23) and a second photovoltaic plate (24), the mounting frame (21) is arranged on the upper portions of the front side and the rear side of the electrolytic cell (1), the first photovoltaic plate (22) is arranged on the upper portion of the mounting frame (21) in a rotating mode, the first photovoltaic plate (22) is electrically connected with the storage battery (12), the connecting frame (23) is arranged on the left side and the right side of the top of the electrolytic cell (1), the second photovoltaic plate (24) is arranged on the upper portion of the connecting frame (23) in a rotating mode, and the second photovoltaic plate (24) is electrically connected with the storage battery (12).

3. The solar photovoltaic power generation concealed pipe drainage equipment according to claim 2, wherein the adjusting mechanism (30) comprises a shaft sleeve (31), a first transmission shaft (32), a first screw rod (33), a first threaded pipe (34), a bevel gear (35), a second screw rod (36), a second threaded pipe (37), a chain wheel (38) and a chain belt (39), the shaft sleeve (31) is arranged in the middle of the upper side of the connecting frame (23) on the right side, the first transmission shaft (32) is slidably arranged on the lower side of the shaft sleeve (31), the first screw rod (33) is rotatably arranged on the upper side of the middle part of the inner side of the first photovoltaic plate (22), the first threaded pipe (34) is threadedly arranged between the inner sides of the first screw rods (33), the bevel gear (35) is respectively arranged on the front side of the first threaded pipe (34) and the left side of the first transmission shaft (32), the bevel gears (35) are mutually engaged, the second screw rod (36) is rotatably arranged on the upper side of the middle part of the inner side of the second photovoltaic plate (24), a second threaded pipe (37) is arranged between the inner sides of the second screw rods (36) in a threaded manner, chain wheels (38) are arranged on the right side of the second threaded pipe (37) and the left side of the first transmission shaft (32), and chain belts (39) are wound between the chain wheels (38).

4. The solar photovoltaic power generation concealed pipe drainage device according to claim 3, wherein the settling mechanism (40) comprises a settling tank (41), a support frame (42), an adapter frame (43), a water outlet valve (44) and a transverse plate (45), the adapter frame (43) is arranged at the lower portion of the left side of the electrolytic tank (1), the support frame (42) is arranged at the left side of the adapter frame (43), the settling tank (41) is arranged at the top of the support frame (42), the water inlet pipe (9) is communicated with the settling tank (41), the water outlet valve (44) is arranged at the lower side of the middle portion of the left side of the settling tank (41), and the transverse plate (45) is arranged between the middle portions of the front side and the rear side of the top of the settling tank (41).

5. The solar photovoltaic power generation concealed pipe drainage equipment according to claim 4, wherein the decontamination mechanism (50) comprises a scraper (51), a filter screen (52), a connecting rod (53), a connecting sleeve (54), a guide rod (55), a compression spring (56) and a guide rail (57), the scraper (51) is slidably arranged on the right side of the inner bottom of the sedimentation tank (41), the filter screen (52) is arranged in the middle of the scraper (51), the connecting rod (53) is arranged on each of the front side and the rear side of the left side of the scraper (51), the connecting sleeve (54) is arranged between the tops of the connecting rods (53), the guide rod (55) is slidably arranged on each of the front side and the rear side of the inner side of the connecting sleeve (54), the compression spring (56) is arranged between the inner sides of the guide rods (55), the guide rail (57) is arranged on the upper portion of the inner side of the sedimentation tank (41), and the outer side of the guide rod (55) is in contact with the tops of the guide rail (57).

6. The solar photovoltaic power generation concealed pipe drainage device according to claim 5, further comprising a feeding mechanism (60) for automatically feeding sodium carbonate, wherein the feeding mechanism (60) comprises a rotating shaft (61), a round material frame (62), a material blocking plate (63), a hopper (64), a blocking cover (65), a second transmission shaft (66), a first gear (67), a second gear (68), a floating plate (69), a transmission wheel (610) and a transmission belt (611), the round material frame (62) is arranged on the front side and the rear side of the upper portion of the transverse plate (45), the rotating shaft (61) is rotatably arranged between the middle portions of the round material frames (62), the material blocking plates (63) are arranged on the front side and the rear side of the rotating shaft (61), the material blocking plates (63) are both positioned inside the round material frame (62) on the same side, the hopper (64) is arranged between the tops of the round material frames (62), the blocking covers (65) are rotatably arranged on the front side and the rear side of the upper portion of the hopper (64), keep off lid (65) and all block the top of hopper (64), the equal rotary type in both sides is equipped with second transmission shaft (66) around diaphragm (45) upper portion, second transmission shaft (66) are located the outside of circle material frame (62), both sides all are equipped with first gear (67) around pivot (61), first gear (67) are located the outside of striker plate (63), second transmission shaft (66) inboard all is equipped with second gear (68), second gear (68) all meshes with first gear (67) of homonymy, the equal rotary type in upside middle part of both sides is equipped with kickboard (69) around sedimentation tank (41), the kickboard (69) outside all is equipped with drive wheel (610) with second transmission shaft (66) outside, all around there being drive belt (611) between two drive wheels (610) of same vertical direction.

7. The solar photovoltaic power generation concealed pipe drainage equipment according to claim 6, further comprising a driving mechanism (70) for automatically moving the connecting sleeve (54), wherein the driving mechanism (70) comprises a bottom plate (71), a speed reducing motor (72), a screw shaft (73) and a screw sleeve (74), the bottom plate (71) is arranged at the upper part of the left side of the sedimentation tank (41), the speed reducing motor (72) is arranged at the top of the bottom plate (71), the screw shaft (73) is arranged on an output shaft of the speed reducing motor (72), the right side of the screw shaft (73) is rotatably connected with the sedimentation tank (41), the screw sleeve (74) is arranged on the right side of the screw shaft (73) in a threaded manner, and the lower part of the screw sleeve (74) is connected with the connecting sleeve (54).

8. The solar photovoltaic power generation concealed conduit drainage equipment according to claim 7, further comprising a pouring mechanism (80) for feeding alkali, wherein the pouring mechanism (80) comprises a box body (81), a sliding cover (82), an L-shaped sliding plate (83), a placing plate (84), a shifting wheel (85), a pull rod (86) and a return spring (87), the box body (81) is arranged at the left part of the front side of the top plate (4), the sliding cover (82) is arranged at the upper part of the inner side of the box body (81) in a sliding manner, the L-shaped sliding plate (83) is arranged at the left part of the lower side of the inner part of the box body (81) in a sliding manner, the placing plate (84) is arranged at the lower part of the inner side of the box body (81) in a rotating manner, the shifting wheels (85) are arranged at the middle parts of the front side and the rear side of the placing plate (84), the pull rods (86) are arranged at the upper parts of the front side and the rear side of the L-shaped sliding plate (83), the right side of the pull rod (86) is contacted with the thumb wheel (85) at the same side, and return springs (87) are arranged between the front side and the rear side of the left side of the bottom of the placing plate (84) and the bottom in the box body (81).

9. The solar photovoltaic power generation concealed pipe drainage equipment according to claim 8, further comprising a curved bar (91) for automatically feeding alkali, a guide frame (92), push pulley (93), release link (94) and awl piece (95), L shape slide (83) left side middle part downside is slidingtype to be equipped with curved bar (91), the upside front portion of electrolysis trough (1) inboard left part is equipped with guide frame (92), guide frame (92) are passed to curved bar (91) downside, curved bar (91) upper portion left side and adapter sleeve (54) contact, sedimentation basin (41) right side upper portion front side is changeed the formula and is equipped with push pulley (93), curved bar (91) upside middle part and push pulley (93) contact, curved bar (91) upper portion left side is equipped with release link (94), release link (94) and adapter sleeve (54) contact, curved bar (91) upside right part is equipped with awl piece (95), can contact with push pulley (93) when awl piece (95) move left.