CN114614760A

CN114614760A - Remote power supply equipment

Info

Publication number: CN114614760A
Application number: CN202210397190.XA
Authority: CN
Inventors: 俄广迅; 陆由付; 李理; 丁笑迎; 王瑞; 宋圆圆; 谢朴峰
Original assignee: Shandong Zhengchen Polytron Technologies Co ltd; Shandong High Speed Group Co Ltd
Current assignee: Shandong Zhengchen Polytron Technologies Co ltd; Shandong High Speed Group Co Ltd
Priority date: 2022-04-15
Filing date: 2022-04-15
Publication date: 2022-06-10
Anticipated expiration: 2042-04-15
Also published as: CN114614760B

Abstract

The invention relates to the field of high-speed power supply equipment, in particular to remote power supply equipment, which comprises a photovoltaic cell panel main body and a fixed shell, wherein the photovoltaic cell panel main body is used for remotely supplying power to electric equipment in an expressway, the fixed shell is fixedly arranged on two sides of the photovoltaic cell panel main body through bolts, a plurality of fixed rods are fixedly arranged at the bottom of the fixed shell through bolts, the bottoms of the fixed rods are welded on the upper end surface of a horizontal plate, guide rods are welded on the lower end surface of the horizontal plate and close to the corners of the horizontal plate, a positioning floating mechanism is arranged at the bottom of each guide rod, a triggering floating mechanism is concentrically arranged on the outer side of each positioning floating mechanism, baffles are welded on the upper end surface of the fixed shell, and movable grooves are formed in the opposite surfaces of the two baffles, and the cleaning process is periodic, and the cleaning effect is effectively guaranteed.

Description

Remote power supply equipment

Technical Field

The invention relates to the field of high-speed power supply equipment, in particular to remote power supply equipment.

Background

The intelligent highway system is applied to multiple types of high-precision road-side electromechanical equipment in a large scale and is integrated electronic equipment, the power consumption of the intelligent highway system has a high dynamic fluctuation characteristic, and power supply with high power, high quality and high stability is required as a basic guarantee. High-speed power supply has the openness, can accept old energy such as "coal electricity", also can accept novel energy such as wind energy, solar energy, can also accept the electric energy that comes from the energy storage, who accords with the demand and adopts who.

Particularly, when the construction of a highway near a subsidence area of a part of coal mines in the south of China is carried out, a pond is formed due to subsidence of the mined coal mines and rain, underground water and the like. However, due to the fact that the pond is located in a mining area, the pollution of the pond is serious, almost no animal exists in the pond, and only various kinds of algae are flooded. Float formula photovoltaic power plant this moment and build on pond of this type, not only can supply the supply of peripheral many high speed circuit power equipment volume in the vicinity, can also absorb a large amount of sunlight, and then reduce the temperature in pond, slow down the reproduction speed of alga in the pond, and then reduce the moisture in pond and scatter and disappear.

In the current water surface photovoltaic point-sending equipment, because the photovoltaic solar panels are all installed in a side-by-side arrangement mode, the cell panels are relatively dense, when impurities are attached to the surfaces of the light-passing plates (namely, toughened glass on the outer sides of the cell panels) of the cell panels, the cleaning cost of maintenance personnel is high, the energy loss is high, and the maintenance personnel cannot properly utilize renewable resources to perform self-cleaning operation on the light-passing plates.

Disclosure of Invention

The invention provides remote power supply equipment, aiming at the problems that in the prior art, external impurities are remained on the surface of toughened glass of a photovoltaic cell panel along with natural wind, so that the light transmittance is low and the impurity cleaning cost is high.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a remote power supply unit, includes the photovoltaic cell board main part that carries out remote power supply to consumer in the highway and carries out the fixed shell that outside protection was used to the photovoltaic cell board main part, the both sides of photovoltaic cell board main part all have fixed shell through bolt fixed mounting, and bolt fixed mounting has a plurality of dead lever, a plurality of is passed through to the bottom of fixed shell the bottom of dead lever is all welded at the up end of horizontal plate, and the lower terminal surface of horizontal plate and all weld near its corner have a guide bar, and location flotation mechanism is installed to the bottom of guide bar, and location flotation mechanism's the outside has arranged with one heart and has triggered flotation mechanism.

The utility model discloses a damping groove, including fixed shell, movable groove, bearing, driving rope, fixed shell, the baffle has all been welded to the up end of fixed shell, two the activity groove has all been seted up to the opposite face department of baffle be provided with the clearance roller between the baffle, and gyro wheel and bearing are all installed in proper order to the both ends of clearance roller, and the bearing is located the activity inslot, and the up end of fixed shell just is located the gyro wheel and has seted up the damping groove under the position, and the higher one end outside position of fixed shell's level is provided with the pipe, and the outer wall embedding of pipe has the driving rope, and the other end of driving rope passes the activity groove and installs the outer wall at the bearing.

Specifically, location floating mechanism is including installing the location floating block in a plurality of dead lever bottoms, the aqua storage tank has been seted up to inside wherein one side of location floating block, the inlet opening has been seted up to bottom one side of aqua storage tank, the locating lever is installed to the vertical direction symmetry in inside of aqua storage tank, the outer wall of locating lever has cup jointed the drive floating block, the up end symmetry embedding of drive floating block has the actuating lever, and the subregion of actuating lever runs through in the top of aqua storage tank, the actuating lever top of outer hourglass in location floating block up end is connected with drive assembly, the intercommunication groove has been seted up to the outer wall of location floating block and be located the inlet opening position directly over.

Specifically, trigger floating mechanism and including cup jointing the floating block that triggers of floating block lateral wall in the location with one heart, trigger the up end symmetry of floating block and seted up first water receiving tank and second water receiving tank, first sector hole has been seted up towards one side corner of the floating block in location to the bottom of first water receiving tank, second sector hole has been seted up towards one side corner of the floating block in location to the bottom of second water receiving tank, the arc hole has been seted up to the bottom of first water receiving tank position placed in the middle, the position is provided with seal assembly directly over the second water receiving tank.

Specifically, drive assembly includes and bonds the displacement board at the actuating lever top end face through glue, and the displacement board cup joints at the outer wall of guide bar, and displacement board one end up end department fixed mounting of actuating lever dorsad has the spliced pole, and one side position of spliced pole is provided with the locating plate, and the bottom fixed mounting of locating plate floats the up end of piece, two in the location spacing spout has all been seted up to the inner wall of locating plate, two be provided with the wire roller between the locating plate, the both ends of wire roller are rotated and are connected with spacing slider, and spacing slider corresponds and install in spacing spout, and spacing slider's lower terminal embedding has the connection rope, connects the terminal fixedly connected with protruding template of rope.

Specifically, fixed shell still includes and is in two through bolt fixed mounting the support arm of baffle lateral wall, every the arc limiting plate has all been welded to the inside wall of support arm, and two of same support arm one side the inner wall of arc limiting plate all is near the outer wall at the pipe, two the clearance department of support arm is provided with the linkage rope, and the one end embedding of linkage rope is at the outer wall of pipe, and the other end of linkage rope is walked around the inside of wire roller embedding at the spliced pole.

It is specific, seal assembly includes the free bearing of floating the piece up end in the location through bonding fixed mounting, the top of free bearing is connected with the deflection piece through the pivot, the deflection piece orientation triggers one side outer wall fixed mounting that floats the piece has the stripper plate, the end department of stripper plate articulates there is the digging arm, the bottom of digging arm articulates there is the extrusion slider, the up end symmetry fixed mounting that floats the piece in the location has the backup pad, the terminal fixed mounting of backup pad has T type guide rail, the closing plate has been cup jointed to the outer wall of T type guide rail, the up end position placed in the middle of the closing plate has been seted up the sliding groove, and extrusion slider slidable mounting is in the sliding groove, the closing plate is close to its interior outer wall position equidistant hole of permeating water of having seted up.

Specifically, the outer wall of the triggering floating block is symmetrically provided with positioning ropes close to the upper position, any two adjacent triggering floating blocks are fixed through the positioning ropes, and the tail end of the positioning rope close to the edge of the pond is provided with a limiting ring used for being fixed with the geological layer of the pond.

Specifically, the height difference between the upper end surface of the driving suspension block and the top of the water storage tank, the length of the photovoltaic cell panel main body, the height of the guide rod and the like are large.

Specifically, the mass of the deflection block is greater than that of the extrusion plate, and the horizontal height of the end head of the extrusion plate at the maximum deflection angle is higher than the horizontal height of the horizontal plane where the gravity center of the deflection block is located.

The invention has the beneficial effects that:

(1) according to the remote power supply equipment, aiming at the water surface photovoltaic power generation equipment in the power supply equipment, a plurality of photovoltaic cell panel main bodies are arranged on the positioning floating mechanism and the triggering floating mechanism assembly, when rain weather occurs, part of rain water is collected into the triggering floating mechanism, the gravity is increased to enable the triggering floating mechanism to enter a working state, the cleaning roller shaft is driven to clean the toughened glass of the photovoltaic cell panel main bodies, so that the light transmittance of the toughened glass is ensured, the power generation efficiency of the photovoltaic cell panel main bodies is higher, the whole cleaning process is completely participated by renewable resources, and the energy saving performance of the equipment is effectively improved.

(2) According to the remote power supply equipment, the sealing assembly and other components are arranged, when rainwater falls, the cleaning roller shaft can clean toughened glass of the photovoltaic cell panel body together with natural rainfall, when the rainfall weather is changed into fine weather, the evaporation of the rainwater is accelerated by sunshine, the rainwater stored in the first water receiving tank can be used as a timing device, the evaporation time is the next cleaning period, the rainwater in the second water receiving tank is stored in the closed space under the action of the sealing assembly, once the rainwater in the first water receiving tank is evaporated, the rainwater in the second water receiving tank can be quickly supplied to the first water receiving tank, namely, the toughened glass can be cleaned for the second time within a certain period, and the light transmittance of the photovoltaic cell panel body is further ensured.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of multiple integral field assemblies of the present invention;

FIG. 2 is a perspective view of a single unitary structure of the present invention;

FIG. 3 is a partial perspective view of the present invention;

FIG. 4 is a side view of the overall structure of the present invention;

FIG. 5 is a cross-sectional view taken along line M-M of FIG. 4 in accordance with the present invention;

FIG. 6 is an enlarged, fragmentary view of area A of FIG. 2 in accordance with the present invention;

fig. 7 is a side view of the wire roller shaft of the present invention;

FIG. 8 is an enlarged partial view of area B of FIG. 2 in accordance with the present invention;

FIG. 9 is a sectional view of the present invention in an operating state;

in the figure: 1. a photovoltaic cell panel body; 2. fixing the housing; 3. fixing the rod; 4. a horizontal plate; 5. a guide bar; 6. positioning a floating mechanism; 7. triggering a floating mechanism; 8. positioning the rope; 21. a baffle plate; 22. a movable groove; 23. a drive rope; 24. cleaning the roll shaft; 25. a damping slot; 26. a roller; 27. a circular tube; 61. positioning a floating block; 62. a water storage tank; 63. positioning a rod; 64. positioning a rod; 65. driving the suspension block; 66. a drive rod; 67. a communicating groove; 68. a drive assembly; 71. triggering the floating block; 72. a first water receiving tank; 73. a second water receiving tank; 74. a first sector hole; 75. an arc-shaped hole; 76. and a second fan-shaped hole. 77. A seal assembly; 681. a displacement plate; 682. connecting columns; 683. positioning a plate; 684. a limiting chute; 685. a wire roll shaft; 686. a limiting slide block; 687. a convex plate; 688. connecting ropes; 91. a support arm; 92. an arc limiting plate; 93. a linkage rope; 771. hinging seat; 772. a deflection block; 773. a pressing plate; 774. a movable arm; 775. a sliding slot; 776. extruding the slide block; 777; a sealing plate; 778. water permeable holes, 779, T-shaped guide rails; 770. and a support plate.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The following terms are defined based on the functions of the present invention, and may be different depending on the intention of the user or the operator or the convention. Therefore, these terms are defined based on the entire contents of the present specification.

Referring to fig. 1, the remote power supply device of the invention comprises a photovoltaic cell panel main body 1 for remotely supplying power to electrical equipment in an expressway and a fixed shell 2 for protecting the exterior of the photovoltaic cell panel main body 1, wherein the fixed shell 2 is fixedly installed on both sides of the photovoltaic cell panel main body 1 through bolts, a plurality of fixed rods 3 are fixedly installed at the bottom of the fixed shell 2 through bolts, the bottoms of the fixed rods 3 are welded on the upper end surface of a horizontal plate 4, guide rods 5 are welded on the lower end surface of the horizontal plate 4 and close to the corners of the horizontal plate 4, a positioning floating mechanism 6 is installed at the bottom of each guide rod 5, a triggering floating mechanism 7 is concentrically arranged on the outer side of each positioning floating mechanism 6, the positioning floating mechanism 6 and the positioning floating mechanism 6 for laying the photovoltaic cell panel main body 1 are laid on the water surface of a pond, and the fixed rods 3 are different in length, after the photovoltaic solar panel is connected with the fixed shell 2, the photovoltaic cell panel main body 1 fixed on the fixed shell 2 has a certain natural inclination angle, so that the vertical area of the photovoltaic cell panel main body 1 and illumination is effectively increased, the light absorption efficiency is higher, and electric energy generated by the photovoltaic cell panel main body 1 through illumination is transmitted to electric equipment of a high-speed circuit through a power transmission line to provide remote power supply; after the plurality of photovoltaic cell panel main bodies 1 are laid on the water surface of the pond, most illumination is blocked by the photovoltaic cell panel main bodies, the direct action area of the illumination on the lake surface is reduced, the multiplication of harmful algae in the pond is effectively blocked, and the ecological environment of the pond is effectively guaranteed.

Referring to fig. 1 and 2, baffles 21 are welded on the upper end face of the fixed housing 2, movable grooves 22 are formed in opposite faces of the two baffles 21, a cleaning roller shaft 24 is arranged between the two baffles 21, rollers 26 and bearings are sequentially mounted at two ends of the cleaning roller shaft 24, the bearings are located in the movable grooves 22, damping grooves 25 are formed in the upper end face of the fixed housing 2 and located right below the rollers 26, a round pipe 27 is arranged at the outer side of the higher horizontal end of the fixed housing 2, a driving rope 23 is embedded in the outer wall of the round pipe 27, the other end of the driving rope 23 penetrates through the movable grooves 22 and is mounted on the outer wall of the bearings, the cleaning roller shaft 24 for cleaning magazines on the surface of the toughened glass of the photovoltaic cell panel body 1 is located at the bottom of the baffles 21 under the action of self gravity in an initial state, the driving rope 23 is stretched under the action of the gravity of the cleaning roller shaft 24, the other end of the drive cord 23 pulls the round tube 27 against the top end face of the stationary housing 2.

Referring to fig. 3-5, the positioning floating mechanism 6 includes a positioning floating block 61 installed at the bottom of the plurality of fixing rods 3, a water storage tank 62 is provided at one side of the inside of the positioning floating block 61, a water inlet 63 is provided at one side of the bottom of the water storage tank 62, positioning rods 64 are symmetrically installed in the vertical direction of the inside of the water storage tank 62, a driving suspension block 65 is sleeved on the outer wall of the positioning rod 64, a driving rod 66 is symmetrically embedded in the upper end surface of the driving suspension block 65, a partial region of the driving rod 66 penetrates through the top of the water storage tank 62, the top of the driving rod 66 which leaks out of the upper end surface of the positioning floating block 61 is connected with a driving assembly 68, a communicating groove 67 is provided at a position right above the water inlet 63 on the outer wall of the positioning floating block 61, and the positioning floating block 61 floats on the water surface of the pond in normal weather which indicates sunny and cloudy days.

Referring to fig. 3-5, the triggering floating mechanism 7 includes a triggering floating block 71 concentrically sleeved on the outer side wall of the positioning floating block 61, a first water receiving groove 72 and a second water receiving groove 73 are symmetrically formed on the upper end surface of the triggering floating block 71, a first fan-shaped hole 74 is formed at a corner of the bottom of the first water receiving groove 72 facing to one side of the positioning floating block 61, a second fan-shaped hole 76 is formed at a corner of the bottom of the second water receiving groove 73 facing to one side of the positioning floating block 61, an arc-shaped hole 75 is formed at a central position of the bottom of the first water receiving groove 72, a sealing assembly 77 is arranged right above the second water receiving groove 73, when natural rainfall occurs, rainwater is poured into the first water receiving groove 72 and the second water receiving groove 73, so that the overall gravity of the triggering floating block 71 is increased, the water inlet amount at the bottom of the triggering floating block 71 is increased, and it can be understood that the water inlet amount refers to the depth of the bottom of the triggering floating block 71 entering the water surface of the pond, when rainwater contacts with the positioning floating block 61, only a small amount of rainwater remains on the surface of the positioning floating block 61, and the change of the water inlet quantity at the bottom of the positioning floating block 61 is relatively small, so that after the first water receiving groove 72 and the second water receiving groove 73 enter rainwater, the triggering floating block 71 has a trend of relatively vertically moving downwards relative to the positioning floating block 61, after the first water receiving groove 72 and the second water receiving groove 73 are filled with rainwater, the arc-shaped hole 75 in the triggering floating block 71 forms a channel with the water inlet hole 63 in the positioning floating block 61, the rainwater in the first water receiving groove 72 flows to the water storage groove 62, and it is worth noting that in an initial state (namely normal weather), the height difference between the upper end surface of the triggering floating block 71 and the upper end surface of the water storage groove 62 is the same as the height difference between the arc-shaped hole 75 and the water inlet hole 63, so that when rainwater flows to the water storage groove 62, the water storage groove 62 is filled with rainwater, the driving suspension block 65 arranged in the driving suspension block will rise vertically under the action of buoyancy, the rising of the driving suspension block 65 will drive the driving rod 66 to rise, and the rising of the driving rod 66 will trigger the driving component 68 to work.

Referring to fig. 5-9, the driving assembly 68 includes a displacement plate 681 bonded to the top end surface of the driving rod 66 by glue, the displacement plate 681 is sleeved on the outer wall of the guide rod 5, a connection post 682 is fixedly mounted on the upper end surface of one end of the displacement plate 681 facing away from the driving rod 66, a positioning plate 683 is disposed on one side of the connection post 682, the bottom of the positioning plate 683 is fixedly mounted on the upper end surface of the positioning floating block 61, a position-limiting sliding groove 684 is formed on the inner wall of each of the two positioning plates 683, a wire roller shaft 685 is disposed between the two positioning plates 683, two ends of the wire roller shaft 685 are rotatably connected with position-limiting sliding blocks 686, the position-limiting sliding blocks 686 are correspondingly mounted in the position-limiting sliding grooves 684, a connection rope 688 is embedded in the lower end surface of the position-limiting sliding blocks 686, a convex plate 687 is fixedly connected to the tail ends of the connection rope 688, the fixed housing 2 further includes a support arm 91 fixedly mounted on the outer side walls of the two baffles 21 by bolts, the inner side wall of each supporting arm 91 is welded with an arc limiting plate 92, the inner walls of the two arc limiting plates 92 on one side of the same supporting arm 91 are abutted against the outer wall of the circular tube 27, a linkage rope 93 is arranged at the gap between the two supporting arms 91, one end of the linkage rope 93 is embedded in the outer wall of the circular tube 27, the other end of the linkage rope 93 is embedded in the connecting column 682 by bypassing the wire roller shaft 685, the driving rod 66 is driven to drive the displacement plate 681 and the connecting column 682 to ascend together, the connecting column 682 is driven to pull the linkage rope 93 after ascending vertically, so that the end of the linkage rope 93 which is not connected with the connecting column 682 has a pulling force which directly acts on the circular tube 27, the circular tube 27 drives the cleaning roller shaft 24 to move from the initial position to the top of the photovoltaic cell panel main body 1 by the driving rope 23, and the roller 26 rolls along the damping groove 25 due to a certain friction force existing between the roller 26 and the damping groove 25, thereby rolling gyro wheel 26 drives clearance roller 24 and rolls to the top of photovoltaic cell board main part 1, the realization is to the cleaning work who avoids toughened glass to photovoltaic cell board main part 1, thereby effectively guarantee to the luminousness of photovoltaic cell board main part 1, and this process does not have the participation of any non-renewable energy, through rainwater renewable resources's utilization, the loss and the use cost of the energy have been reduced, this process linkage rope 93 still will drive wire roller 685 and spacing slider 686 and rise along spacing spout 684 earlier, spacing slider 686 removes and drives seal assembly 77 work.

Referring to fig. 3-8, the sealing assembly 77 includes a hinged support 771 fixedly mounted on the upper end surface of the positioning floating block 61 by bonding, the top of the hinged support 771 is connected with a deflection block 772 via a rotating shaft, the outer wall of one side of the deflection block 772 facing the triggering floating block 71 is fixedly mounted with a squeezing plate 773, the end of the squeezing plate 773 is hinged with a movable arm 774, the bottom of the movable arm 774 is hinged with a squeezing slider 776, the upper end surface of the positioning floating block 61 is symmetrically and fixedly mounted with a support plate 770, the tail end of the support plate 770 is fixedly mounted with a T-shaped guide rail 779, the outer wall of the T-shaped guide rail 779 is sleeved with a sealing plate 777, the middle position of the upper end surface of the sealing plate 777 is provided with a sliding groove 775, the squeezing slider 776 is slidably mounted in the sliding groove 775, the sealing plate 777 is provided with water permeable holes 778 at equal intervals near the inner and outer wall thereof, when the limiting slider 686 vertically rises, the connecting rope 688 drives a protrusion 687 connected with the other end thereof to rise, after the convex plate 687 rises, the upper end face of one end of the convex plate applies thrust to the bottom of the deflection block 772, the deflection block 772 deflects by taking the rotating shaft as the axis under the action of the thrust, the horizontal height of one end of the extrusion plate 773 descends after deflection, the end of the movable arm 774 applies extrusion force to one end of the movable arm 774, the movable arm 774 directly applies the force to the extrusion slide block 776, the horizontal height of the extrusion slide block 776 is reduced while the extrusion slide block 776 slides in the slide groove 775, thereby driving the sealing plate 777 to slide down along the T-shaped guiding track 779 until the lower end surface of the sealing plate 777 abuts against the upper end surface of the trigger floating block 71, it should be noted that when the wire roll shaft 685 rises to the maximum value along the limiting sliding grooves 684, the sealing plate 777 also abuts against the upper end surface of the trigger floating block 71, at this time, the second water receiving tank 73 is changed from an initial open state to a sealed state, and the sealing surface of a second fan-shaped hole 76 at the bottom corner of the second water receiving tank 73 is the outer side wall of the positioning floating block 61; when the holes 778 of permeating water are used for rainwater to fall, the quick water conservancy diversion of permeable holes 778 reaches second water receiving tank 73, and the vertical direction of a plurality of holes 778 of permeating water is seted up the position and is all in the outside of second water receiving tank 73, guarantees that the holes 778 of permeating water can not cause the influence to the sealed effect of closing plate 777.

Referring to fig. 1, positioning ropes 8 are symmetrically installed at upper positions of outer walls of the trigger floating blocks 71, any two adjacent trigger floating blocks 71 are fixed through the positioning ropes 8, wherein a limiting ring for fixing with a geological layer of a pond is installed at the tail end of the positioning rope 8 close to the edge of the pond, two adjacent trigger floating blocks 71 are subjected to regional constraint through the positioning ropes 8, the stability between the adjacent trigger floating blocks 71 is improved, the limiting ring can be installed at the tail end of the positioning rope 8 at one side of the trigger floating block 71 close to the edge of the pond, and can also be replaced by a square ring, in the specific operation process, one end of the positioning rope 8 with the limiting ring is pulled to the surface of the geological layer at the edge of the pond, a ground nail for positioning and locking passes through an inner ring of the limiting ring, the tip of the ground nail is inserted into the geological layer (generally, soil) of the pond, and finally a knocking tool is used, if the hammer strikes the ground nail, the ground nail is completely knocked into the geological layer of the pond, and then fixation can be completed.

Referring to fig. 1-3, the height difference between the upper end surface of the driving suspension block 65 and the top of the water storage tank 62, the length of the photovoltaic cell panel main body 1, the height of the guide rod 5 and the like are large, so that when the driving suspension block 65 is lifted to the highest point, the cleaning roller 24 can clean the port glass on the surface of the photovoltaic cell panel main body 1.

Referring to fig. 4-9, the mass of the deflection block 772 is greater than that of the pressing plate 773, and the horizontal height of the end of the pressing plate 773 at the maximum deflection angle is higher than that of the horizontal plane of the center of gravity of the deflection block 772, when the natural weather is changed into a clear weather, the first water receiving tank 72 is open, sunlight directly irradiates the top of the first water receiving tank 72, rainwater stored in the first water receiving tank 72 is taken as a timing device, when the rainwater in the first water receiving tank 72 is evaporated, the overall mass of the floating block 71 is triggered to decrease, the first water receiving tank 72 returns to the initial position, that is, each component of the invention returns to the initial position, because the second water receiving tank 73 is provided with the sealing component 77, the two components have different volatilization rates, when the first water receiving tank 72 volatilizes, the suspension block 65 is driven to reset, the communication groove 67, the first fan-shaped hole 74 and the second water receiving tank 73 form a communication path, the water in the second water storage tank 73 enters the first water receiving tank 72 again along the communicating groove 67, and then the process is carried out according to the above, so as to realize the purpose of Huhu cycle. The effect of cleaning for many times is realized.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a remote power supply unit, includes that the photovoltaic cell board main part (1) that carries out remote power supply to consumer in the highway and carry out fixed shell (2) that outside protection was used to photovoltaic cell board main part (1), its characterized in that: the both sides of photovoltaic cell board main part (1) all have fixed casing (2) through bolt fixed mounting, and there are a plurality of dead lever (3), a plurality of bottom through bolt fixed mounting of fixed casing (2) the up end at horizontal plate (4) is all welded in the bottom of dead lever (3), and the lower terminal surface of horizontal plate (4) and be close to its corner and all weld guide bar (5), and location flotation mechanism (6) are installed to the bottom of guide bar (5), and the outside of location flotation mechanism (6) is arranged with one heart and is triggered flotation mechanism (7).

2. A remote power supply apparatus as claimed in claim 1, wherein: baffle (21), two have all been welded to the up end of fixed shell (2) movable groove (22), two have all been seted up in the opposite face department of baffle (21) be provided with clearance roller (24) between baffle (21), gyro wheel (26) and bearing are all installed in proper order to the both ends of clearance roller (24), and the bearing is located movable groove (22), and damping groove (25) have been seted up to the up end of fixed shell (2) and the position that is located gyro wheel (26) under, the higher one end outside position of the level of fixed shell (2) is provided with pipe (27), the outer wall embedding of pipe (27) has driving rope (23), the other end of driving rope (23) passes movable groove (22) and installs the outer wall at the bearing.

3. A remote power supply apparatus as claimed in claim 1, wherein: the utility model discloses a floating mechanism, including installing location floating block (61) in a plurality of dead lever (3) bottoms in location floating mechanism (6), aqua storage tank (62) have been seted up to inside one side of location floating block (61), inlet opening (63) have been seted up to bottom one side of aqua storage tank (62), locating lever (64) are installed to the inside vertical direction symmetry of aqua storage tank (62), drive suspension block (65) have been cup jointed to the outer wall of locating lever (64), the up end symmetry embedding of drive suspension block (65) has actuating lever (66), and the subregion of actuating lever (66) runs through in the top of aqua storage tank (62), the actuating lever (66) top of leaking outward in location floating block (61) up end is connected with drive assembly (68), the outer wall of location floating block (61) just is located inlet opening (63) and has seted up intercommunication groove (67).

4. A remote power supply apparatus as claimed in claim 3, wherein: trigger floating mechanism (7) including concentric cup jointing in the floating block (71) that triggers of location flotation block (61) lateral wall, trigger the up end symmetry of floating block (71) and seted up first water receiving tank (72) and second water receiving tank (73), first fan-shaped hole (74) have been seted up towards one side corner of location flotation block (61) to the bottom of first water receiving tank (72), second fan-shaped hole (76) have been seted up towards one side corner of location flotation block (61) to the bottom of second water receiving tank (73), arc hole (75) have been seted up to the bottom position placed in the middle of first water receiving tank (72), position is provided with seal assembly (77) directly over second water receiving tank (73).

5. A remote power supply apparatus as claimed in claim 3, wherein: the driving assembly (68) comprises a displacement plate (681) bonded to the top end face of the driving rod (66) by glue, and the displacement plate (681) is sleeved on the outer wall of the guide rod (5), the upper end face of one end of the displacement plate (681) back to the drive rod (66) is fixedly provided with a connecting column (682), one side of the connecting column (682) is provided with a positioning plate (683), the bottom of the positioning plate (683) is fixedly arranged on the upper end face of the positioning floating block (61), the inner walls of the two positioning plates (683) are both provided with a limit sliding chute (684), a lead roll shaft (685) is arranged between the two positioning plates (683), the two ends of the lead roll shaft (685) are rotatably connected with limit sliding blocks (686), and the limiting sliding block (686) is correspondingly installed in the limiting sliding groove (684), the lower end face of the limiting sliding block (686) is embedded with a connecting rope (688), and the tail end of the connecting rope (688) is fixedly connected with a convex plate (687).

6. A remote power supply apparatus as claimed in claim 5, wherein: the fixed shell (2) further comprises support arms (91) fixedly mounted on the outer side walls of the two baffle plates (21) through bolts, arc-shaped limiting plates (92) are welded on the inner side walls of the support arms (91), the inner walls of the two arc-shaped limiting plates (92) on one side of the same support arm (91) are close to the outer wall of the circular tube (27), a linkage rope (93) is arranged in a gap of the two support arms (91), one end of the linkage rope (93) is embedded in the outer wall of the circular tube (27), and the other end of the linkage rope (93) bypasses a wire roller shaft (685) and is embedded in the connecting column (682).

7. A remote power supply apparatus as claimed in claim 4, wherein: the sealing assembly (77) comprises a hinged support (771) fixedly installed on the upper end face of the positioning floating block (61) through bonding, the top of the hinged support (771) is connected with a deflection block (772) through a rotating shaft, an extrusion plate (773) is fixedly installed on the outer wall of one side of the deflection block (772) facing the triggering floating block (71), a movable arm (774) is hinged to the end of the extrusion plate (773), an extrusion sliding block (776) is hinged to the bottom of the movable arm (774), a supporting plate (770) is symmetrically and fixedly installed on the upper end face of the positioning floating block (61), a T-shaped guide rail (779) is fixedly installed at the tail end of the supporting plate (770), a sealing plate (777) is sleeved on the outer wall of the T-shaped guide rail (779), and a sliding groove (775) is formed in the middle position of the upper end face of the sealing plate (777), and the extrusion sliding block (776) is arranged in the sliding groove (775) in a sliding way, and the position of the sealing plate (777) close to the inner wall and the outer wall is provided with water permeable holes (778) at equal intervals.

8. A remote power supply apparatus as claimed in claim 4, wherein: the outer wall that triggers floating block (71) is leaned on last position symmetry to install location rope (8), and arbitrary two adjacent triggering floating blocks (71) between all fixed through location rope (8), wherein is close to the spacing ring that is used for with pond geological stratification is fixed in location rope (8) end at pond edge.

9. A remote power supply apparatus as claimed in claim 3, wherein: the height difference between the upper end surface of the driving suspension block (65) and the top of the water storage tank (62), the length of the photovoltaic cell panel main body (1), the height of the guide rod (5) and the like are large.

10. A remote power supply apparatus as claimed in claim 7, wherein: the mass of the deflection block (772) is larger than that of the extrusion plate (773), and the horizontal height of the end head of the extrusion plate (773) at the maximum deflection angle is higher than that of the horizontal plane where the gravity center of the deflection block (772) is located.