CN111605240A

CN111605240A - Take hydraulic power generation device for river course of refuse collection compression function

Info

Publication number: CN111605240A
Application number: CN202010524351.8A
Authority: CN
Inventors: 高上犁
Original assignee: Yiwu Chuchen New Energy Technology Co Ltd
Current assignee: Nanjing Lishui Hi Tech Industry Equity Investment Co Ltd
Priority date: 2020-06-10
Filing date: 2020-06-10
Publication date: 2020-09-01
Anticipated expiration: 2040-06-10
Also published as: GB202014387D0; CN111605240B

Abstract

The invention discloses a hydraulic power generation device with a garbage collection and compression function for a river channel; including the main part case, terminal surface fixedly connected with spud pile under the main part case, the electricity generation chamber that link up about being equipped with in the main part case, electricity generation chamber upside is equipped with carries the chamber, it is equipped with the filter frame chamber to carry chamber right side intercommunication, it is equipped with rubbish logical chamber to carry the terminal intercommunication left of chamber left end face upside, block rivers through the baffle, thereby accumulate the potential energy of baffle right side surface of water when gathering surface of water rubbish through rivers, thereby the velocity of flow of rivers behind the baffle is opened in the increase, in order to reach the requirement of generating electricity, simultaneously the surface of water descends the cooperation triangle to collect filter frame and accomplish collection and the dry-type separation to rubbish, prevent that rubbish from soaking in the aquatic for a long time and smelly, transport rubbish to the compression intracavity through carrying the filter plate, accomplish the.

Description

Take hydraulic power generation device for river course of refuse collection compression function

Technical Field

The invention relates to the related technical field of hydroelectric power generation equipment, in particular to a hydraulic power generation device with a garbage collection and compression function for a river channel.

Background

Current hydroelectric power generation uses rivers and lakes as the main usually, because small-size river course normal water flow is less, difficult being used for the electricity generation, so at present still remain to be developed to the utilization of small-size flowing river course water conservancy resource, on the other hand, most showy all kinds of rubbish in this kind of small-size river course, there is rubbish to be stirred into the possibility that the flabellum damaged the generator in the electricity generation process, river course rubbish is most salvaged through the manual work at present simultaneously, the efficiency is lower, and the rubbish density that floats in the surface of water is less, the volume is great, collect salvage the back volume great, be unfavorable for subsequent transportation and.

Disclosure of Invention

Aiming at the technical defects, the invention provides a hydraulic power generation device with a garbage collection and compression function for a river channel, which can overcome the defects.

The invention relates to a hydraulic power generation device with a garbage collection and compression function for a river channel, which comprises a main body box, wherein a fixing pile is fixedly connected to the lower end face of the main body box, a power generation cavity which is communicated from left to right is arranged in the main body box, a conveying cavity is arranged on the upper side of the power generation cavity, a filter frame cavity is communicated with the right side of the conveying cavity, a garbage through cavity is communicated from the left end to the left, a compression cavity is communicated with the left side of the garbage through cavity, lifting box cavities are symmetrically arranged on the front side and the rear side of the compression cavity, a power steering cavity is arranged on the lower side of the compression cavity, a forward and reverse rotating cavity is arranged on the rear side of the power steering cavity, a meshing cavity is communicated with the right side of the forward and reverse rotating cavity, a contact sensor positioned between the filter frame cavity and the garbage through cavity is fixedly connected to the right end wall of the main body, the left side of the friction wheel cavity is communicated with a compression limiting cavity, the right end wall of the friction wheel cavity is connected with a friction wheel shaft which extends leftwards into the compression limiting cavity and rightwards to the outside in a rotating fit mode, the friction wheel shaft is fixedly connected with a one-way bearing located in the friction wheel cavity, the one-way bearing is connected with a friction wheel in a rotating fit mode, and the outer end wall of the lifting box cavity is fixedly connected with a friction strip which can be abutted to the friction wheel.

On the basis of the technical scheme, a compression plate is arranged on the outer side of the lifting box, a lifting box rotating cavity with an outward opening is arranged in the compression plate, the friction wheel shaft extends rightwards to be fixedly connected with the right end wall of the lifting box rotating cavity, the outer end wall of the compression limiting cavity is fixedly connected with a compression limiting baffle plate, the left end of the outer end face of the friction wheel shaft is fixedly connected with a compression limiting block which can be abutted against the compression limiting baffle, when the compression plate is in a horizontal state, the lower end surface of the compression limiting block is just abutted against the upper end surface of the compression limiting baffle for limiting, a pressure plate return spring is fixedly connected between the left end surface of the friction wheel shaft and the left end wall of the compression limiting cavity, sleeve transmission cavities are communicated and arranged at the upper sides of the lifting box cavities at the two sides, the upper end face of the lifting box is fixedly connected with a lifting shaft which extends upwards to penetrate through the sleeve transmission cavity to the outside.

On the basis of the technical scheme, the sleeve that symmetry set up around upper end wall normal running fit is connected with in the sleeve transmission intracavity, the ascending and descending epaxial extension runs through the sleeve and with sleeve screw-thread fit connects, sleeve transmission chamber upside is equipped with the lift pulley chamber that extends rear side left, lift pulley chamber lower extreme wall normal running fit is connected with downwardly extending to sleeve transmission intracavity and upwards extend to the sleeve power shaft of lift pulley intracavity, the epaxial fixedly connected with of sleeve power is located sleeve drive gear in the sleeve transmission intracavity, the front side fixedly connected with on the sleeve with the sleeve gear meshing's sleeve gear, sleeve power shaft and rear side power fit is connected with between the sleeve and is located the sleeve drive belt in the sleeve transmission intracavity.

On the basis of the technical scheme, the upper end wall of the power generation cavity is fixedly connected with a fan blade box, a power generation belt wheel cavity extending upwards into the main body box is arranged in the fan blade box, the right side of the power generation belt wheel cavity is provided with a power generator fixedly connected with the main body box, the left end surface of the power generator is fixedly connected with a power generation rotating shaft extending leftwards and penetrating through the power generation belt wheel cavity to the power steering cavity, the left end wall of the power generation belt wheel cavity is connected with a fan blade shaft extending rightwards into the power generation cavity in a rotating and matching manner, the right end of the fan blade shaft is fixedly connected with a fan blade, a power generation driving belt positioned in the power generation belt wheel cavity is connected between the fan blade shaft and the power generation rotating shaft in a power matching manner, the upper side of the power generation cavity is communicated with a baffle plate cavity positioned on the right side of the conveying cavity, a baffle plate is connected in a sliding, and a baffle electromagnet is fixedly connected in the upper end wall of the baffle cavity.

On the basis of the technical scheme, a conveying belt wheel cavity extending rightwards is arranged on the front side of the power steering cavity, a filter frame belt wheel cavity is arranged on the front side of the conveying belt wheel cavity, a conveying shaft extending backwards into the conveying cavity is connected to the inner end wall of the conveying cavity in a vertically symmetrical rotating fit mode, the conveying shaft extends forwards into the conveying belt wheel cavity at the lower side, a conveying belt located in the conveying cavity is connected between the conveying shafts in a power fit mode, a plurality of conveying filter plates arranged at equal intervals are fixedly connected to the outer end face of the conveying belt, a filter frame transmission cavity is arranged between the filter frame belt wheel cavity and the filter frame cavity, a filter frame rotating shaft extending forwards into the filter frame transmission cavity and extending backwards into the filter frame cavity is connected to the inner end wall of the filter frame cavity in a rotating fit mode, a triangular collection filter frame with an initial state lower opening upwards and a left opening is fixedly connected to the rear end of the filter frame, the filter frame transmission cavity is characterized in that a half gear is fixedly connected to the tail end of the front side of the filter frame rotating shaft, and a filter frame reset spring is fixedly connected between the front end face of the filter frame rotating shaft and the front end wall of the filter frame transmission cavity.

On the basis of the technical scheme, a power distribution shaft which extends forwards to penetrate through the belt wheel cavity of the conveying belt and extends backwards to the filter frame belt wheel cavity and the forward and reverse rotation cavity is connected to the front end wall of the power steering cavity in a rotating and matching manner, a conveying transmission belt positioned in the belt wheel cavity of the conveying belt is connected between the conveying shaft at the front side and the power distribution shaft in a rotating and matching manner, a filter frame transmission shaft which extends forwards to the filter frame belt wheel cavity and extends backwards to the filter frame transmission cavity is connected to the front end wall of the filter frame transmission shaft in a rotating and matching manner, a filter frame transmission gear capable of being meshed with the half gear is fixedly connected to the rear end of the filter frame transmission shaft, a filter frame transmission belt positioned in the filter frame belt wheel cavity is connected between the filter frame transmission shaft and the power distribution shaft in a rotating and matching manner, and a first bevel, and a second bevel gear which is fixedly connected with the power distribution shaft and meshed with the first bevel gear is arranged in the power steering cavity.

On the basis of the technical scheme, forward and reverse gears which are in rotating fit connection with the power distribution shaft are symmetrically arranged in the forward and reverse rotating cavity in a front-back mode, forward and reverse bevel gears are fixedly connected to inner end faces of the forward and reverse gears, the forward and reverse bevel gears are fixedly connected with the power distribution shaft in a front side, the forward and reverse bevel gears are in rotating fit connection with the power distribution shaft in a rear side, a transmission bevel gear shaft which extends rightwards into the forward and reverse rotating cavity is in rotating fit connection with the left end wall of the forward and reverse rotating cavity, and a transmission bevel gear which is meshed with the forward and reverse bevel gears is fixedly connected to the tail end of the right.

On the basis of the technical scheme, a bevel gear cavity is arranged at the rear side of the meshing cavity, a forward rotating shaft and a reverse rotating shaft which extend forwards into the meshing cavity and extend backwards into the bevel gear cavity are connected in a rotationally matched manner in the rear end wall of the meshing cavity, a spline shaft is connected in a spline manner at the front end of the forward rotating shaft and the reverse rotating shaft, a magnetic rotating plate is connected in a rotationally matched manner at the front end of the sleeve transmission gear, a forward rotating electromagnet and a reverse rotating electromagnet are fixedly connected in the front end wall of the meshing cavity, a magnetic rotating plate spring is fixedly connected between the front end surface of the magnetic rotating plate and the front end wall of the meshing cavity, a meshing gear which can be meshed with the forward rotating gear and the reverse rotating gear is fixedly connected on the spline shaft, a third bevel gear is fixedly connected in a rotationally matched manner at the rear end of the forward rotating shaft and the reverse rotating electromagnet, a lifting transmission shaft which extends upwards into the lifting belt wheel, and a lifting transmission belt positioned in the lifting belt wheel cavity is connected between the lifting transmission shaft and the sleeve power shaft in a power fit manner.

The invention has the beneficial effects that: stop rivers through the baffle, thereby accumulate the potential energy of baffle right side surface of water in the time of through rivers gathering surface of water rubbish, thereby the velocity of flow of rivers behind the baffle is opened in the increase, in order to reach the power generation requirement, the surface of water descends the cooperation triangle simultaneously and collects the filter frame and accomplish collection and the dry-type separation to rubbish, prevent that rubbish from soaking in the aquatic for a long time and smelly, transport rubbish to the compression intracavity through carrying the filter plate, accomplish the compression to rubbish through the compression board, and restrict its resilience, thereby be convenient for follow-up transportation and utilize.

Drawings

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

FIG. 1 is a schematic structural view of a hydroelectric power generating device with a garbage collection and compression function for a river channel, according to the present invention;

FIG. 2 is a schematic sectional view taken along the line A-A in FIG. 1;

FIG. 3 is a schematic sectional view taken along line B-B in FIG. 1;

FIG. 4 is a schematic cross-sectional view taken along the direction C-C in FIG. 2;

FIG. 5 is a schematic sectional view taken along the direction D-D in FIG. 1;

FIG. 6 is an enlarged schematic view of the structure at E in FIG. 3;

fig. 7 is an enlarged schematic view of the structure at F in fig. 2.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-7, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

As shown in fig. 1-7, the hydraulic power generation device with garbage collection and compression functions for river channels of the device of the invention comprises a main body box 10, a fixing pile 22 is fixedly connected to the lower end face of the main body box 10, a power generation cavity 26 which is through from left to right is arranged in the main body box 10, a conveying cavity 14 is arranged on the upper side of the power generation cavity 26, a filter frame cavity 86 is communicated with the right side of the conveying cavity 14, a garbage through cavity 12 is communicated from left to right at the tail end of the upper side of the left end face of the conveying cavity 14, a compression cavity 11 is communicated with the left side of the garbage through cavity 12, lifting box cavities 24 are symmetrically arranged on the front side and the rear side of the compression cavity 11, a power steering cavity 28 is arranged on the lower side of the compression cavity 11, a forward and reverse rotation cavity 64 is arranged on the rear side of the power steering cavity 28, an engagement cavity 70 is communicated with the right side of the forward and reverse rotation cavity, lift case 49 is connected with in the lift case chamber 24 sliding fit, be equipped with the outside friction pulley chamber 46 of opening in the lift case 49, the intercommunication of friction pulley chamber 46 left side is equipped with compression spacing chamber 39, friction pulley chamber 46 right-hand member wall internal rotation fit is connected with extend to left in the compression spacing chamber 39 and extend to external friction pulley shaft 47 right, fixedly connected with is located on the friction pulley shaft 47 the one-way bearing 43 in the friction pulley chamber 46, the last rotating fit that rotates of one-way bearing 43 is connected with friction pulley 48, lift case chamber 24 outer end wall fixedly connected with can with the friction strip 45 of friction pulley 48 butt.

In addition, in one embodiment, a compression plate 51 is arranged outside the lifting box 49, a lifting box rotating cavity 87 which is opened outwards is arranged in the compression plate 51, the friction wheel shaft 47 extends rightwards to be fixedly connected with the right end wall of the lifting box rotating cavity 87, the outer end wall of the compression limit cavity 39 is fixedly connected with a compression limit baffle 41, the left end of the outer end surface of the friction wheel shaft 47 is fixedly connected with a compression limit block 40 which can be abutted against the compression limit baffle 41, when the compression plate 51 is in a horizontal state, the lower end surface of the compression limiting block 40 is just abutted with the upper end surface of the compression limiting baffle 41 for limiting, a pressure plate return spring 50 is fixedly connected between the left end surface of the friction wheel shaft 47 and the left end wall of the compression limiting cavity 39, sleeve transmission cavities 78 are communicated with the upper sides of the lifting box cavities 24 at the two sides, the upper end face of the lifting box 49 is fixedly connected with a lifting shaft 83 which extends upwards to penetrate through the sleeve transmission cavity 78 to the outside.

In addition, in one embodiment, the sleeve transmission cavity 78 is connected with a sleeve 85 which is rotationally matched and arranged symmetrically in front and back in the upper end wall, the lifting shaft 83 extends upward through the sleeve 85 and is connected with the sleeve 85 in a threaded fit manner, a lifting belt wheel cavity 81 extending towards the left rear side is arranged on the upper side of the sleeve transmission cavity 78, a sleeve power shaft 82 extending downwards into the sleeve transmission cavity 78 and upwards into the lifting belt wheel cavity 81 is connected to the lower end wall of the lifting belt wheel cavity 81 in a rotating and matching manner, a sleeve transmission gear 79 positioned in the sleeve transmission cavity 78 is fixedly connected on the sleeve power shaft 82, a sleeve gear 84 meshed with the sleeve transmission gear 79 is fixedly connected on the sleeve 85 at the front side, a sleeve driving belt 77 positioned in the sleeve driving cavity 78 is connected between the sleeve power shaft 82 and the sleeve 85 at the rear side in a power fit mode.

In addition, in one embodiment, the upper end wall of the power generation cavity 26 is fixedly connected with a fan blade box 23, a power generation pulley cavity 38 extending upwards into the main body box 10 is arranged in the fan blade box 23, the right side of the power generation pulley cavity 38 is provided with a power generator 37 fixedly connected with the main body box 10, the left end surface of the power generator 37 is fixedly connected with a power generation rotating shaft 36 extending leftwards to penetrate through the power generation pulley cavity 38 to the power steering cavity 28, the left end wall of the power generation pulley cavity 38 is connected with a fan blade shaft 27 extending rightwards to the power generation cavity 26 in a rotating fit manner, the right end of the fan blade shaft 27 is fixedly connected with a fan blade 25, a power generation transmission belt 35 located in the power generation pulley cavity 38 is connected between the fan blade shaft 27 and the power generation rotating shaft 36 in a power fit manner, the upper side of the power generation cavity 26 is communicated with a baffle plate cavity 19 located on the right side of the conveying cavity 14, the baffle plate 21 is connected in the baffle plate cavity 19 in a sliding fit mode, a baffle plate spring 20 is fixedly connected between the upper end face of the baffle plate 21 and the upper end wall of the baffle plate cavity 19, and a baffle plate electromagnet 18 is fixedly connected in the upper end wall of the baffle plate cavity 19.

In addition, in one embodiment, a right-extending conveyer belt wheel cavity 34 is arranged at the front side of the power steering cavity 28, a filter frame belt wheel cavity 54 is arranged at the front side of the conveyer belt wheel cavity 34, a conveying shaft 89 extending backwards into the conveying cavity 14 is connected in the front end wall of the conveying cavity 14 in an up-and-down symmetrical rotating fit manner, the conveying shaft 89 at the lower side extends forwards into the conveyer belt wheel cavity 34, a conveying belt 13 positioned in the conveying cavity 14 is connected between the conveying shafts 89 in a power fit manner, a plurality of conveying filter plates 15 arranged at equal intervals are fixedly connected on the outer end surface of the conveying belt 13, a filter frame transmission cavity 53 is arranged between the filter frame belt wheel cavity 54 and the filter frame cavity 86, a filter frame rotating shaft 59 extending forwards into the filter frame transmission cavity 53 and backwards into the filter frame cavity 86 is connected in a rotating fit manner, a triangular collecting filter frame 17 with an upward opening and a leftward opening is fixedly connected at the rear end of the filter frame rotating shaft 59 in an initial state, the end fixedly connected with semi-gear 58 before straining frame pivot 59, straining frame pivot 59 preceding terminal surface with strain fixedly connected with straining frame reset spring 57 between the wall of straining frame transmission chamber 53 front end.

In addition, in one embodiment, a power distribution shaft 31 extending forward through the belt wheel cavity 34 into the filter frame belt wheel cavity 54 and extending backward into the forward and reverse rotation cavity 64 is connected in a rotationally engaged manner to the front end wall of the power steering cavity 28, a conveying belt 33 located in the belt wheel cavity 34 is connected in a rotationally engaged manner between the front side conveying shaft 89 and the power distribution shaft 31, a filter frame transmission shaft 56 extending forward into the filter frame belt wheel cavity 54 and extending backward into the filter frame transmission cavity 53 is connected in a rotationally engaged manner to the front end wall of the filter frame transmission cavity 53, a filter frame transmission gear 52 capable of meshing with the half gear 58 is fixedly connected to the rear end of the filter frame transmission shaft 56, a filter frame transmission belt 55 located in the filter frame belt wheel cavity 54 is connected in a rotationally engaged manner between the filter frame transmission shaft 56 and the power distribution shaft 31, the left end of the power generation rotating shaft 36 is fixedly connected with a first bevel gear 30, and a second bevel gear 29 which is fixedly connected with the power distribution shaft 31 and meshed with the first bevel gear 30 is arranged in the power steering cavity 28.

In addition, in one embodiment, forward and reverse rotation gears 61 connected with the power distribution shaft 31 in a rotationally matched manner are symmetrically arranged in the forward and reverse rotation cavity 64 in a forward and backward manner, forward and reverse rotation bevel gears 60 are fixedly connected to inner end faces of the forward and reverse rotation gears 61, the forward and reverse rotation bevel gears 60 on the front side are fixedly connected with the power distribution shaft 31, the forward and reverse rotation bevel gears 60 on the rear side are connected with the power distribution shaft 31 in a rotationally matched manner, a transmission bevel gear shaft 63 extending rightwards into the forward and reverse rotation cavity 64 is connected with the left end wall of the forward and reverse rotation cavity 64 in a rotationally matched manner, and a transmission bevel gear 62 meshed with the forward and reverse rotation bevel gears 60 is fixedly connected to the right.

In addition, in one embodiment, a bevel gear cavity 75 is arranged at the rear side of the meshing cavity 70, a forward and reverse rotating shaft 71 extending forward into the meshing cavity 70 and extending backward into the bevel gear cavity 75 is connected to the rear end wall of the meshing cavity 70 in a rotationally fitting manner, a spline shaft 69 is connected to the front end of the forward and reverse rotating shaft 71 in a rotationally fitting manner, a magnetic rotating plate 67 is connected to the front end of the sleeve transmission gear 79 in a rotationally fitting manner, a forward and reverse rotating electromagnet 66 is fixedly connected to the front end wall of the meshing cavity 70, a magnetic rotating plate spring 65 is fixedly connected between the front end surface of the magnetic rotating plate 67 and the front end wall of the meshing cavity 70, a meshing gear 68 capable of meshing with the forward and reverse rotating gear 61 is fixedly connected to the spline shaft 69, a third bevel gear 72 is fixedly connected to the rear end of the forward and reverse rotating shaft 71, and a lifting transmission shaft 73 extending upward into the lifting pulley cavity 81 is connected to the lower end wall of the, the tail end of the lower side of the lifting transmission shaft 73 is fixedly connected with a fourth bevel gear 74 meshed with the third bevel gear 72, and a lifting transmission belt 80 positioned in the lifting pulley cavity 81 is connected between the lifting transmission shaft 73 and the sleeve power shaft 82 in a power fit manner.

In the following, the applicant will specifically describe a hydraulic power generating device with garbage collection and compression function for river channels according to the present application with reference to fig. 1 to 7 and the above description: when the river channel fixing device works, the main body box 10 is installed in a river channel, is inserted into a river bed through the fixing piles 22 to be fixed, and flows from right to left after installation; under the blocking action of the baffle 21, the water surface on the right side of the main body box 10 rises, and garbage gathers on the right end surface of the main body box 10 under the action of water flow, when the water surface rises to the position of the contact sensor 16, the contact sensor 16 finishes one-time counting and sends out a signal, so that the baffle electromagnet 18 is started at regular time, the forward and reverse electromagnet 66 is not started when receiving a single-time signal, the baffle electromagnet 18 is started to drive the baffle 21 to overcome the thrust of the baffle spring 20 to move upwards to be opened through the suction force between the baffle electromagnet 18 and the baffle 21, and therefore the water flow on the right side of the main body box 10 flows to the left side of the main body box 10; the water flow drives the fan blades 25 to rotate through the power generation cavity 26, so as to drive the fan blade shaft 27 to rotate, the fan blade shaft 27 rotates to drive the power generation rotating shaft 36 to rotate through the power generation driving belt 35, so as to complete power generation through the power generator 37, the power generation rotating shaft 36 rotates and also drives the power distribution shaft 31 to rotate through the first bevel gear 30 and the second bevel gear 29, the power distribution shaft 31 rotates to drive the front-side forward and reverse bevel gear 60 to rotate and simultaneously drives the lower-side conveying shaft 89 to rotate through the conveying driving belt 33, and the filter frame driving shaft 56 is also driven to rotate through the filter frame driving belt; the filter frame transmission shaft 56 rotates to drive the half gear 58 to rotate through the filter frame transmission gear 52, so as to drive the filter frame rotating shaft 59 to rotate by overcoming the elastic force of the filter frame return spring 57, so as to drive the triangular collection filter frame 17 to rotate, when the filter frame transmission gear 52 rotates to be disengaged from the half gear 58, the triangular collection filter frame 17 just rotates for forty-five degrees to be opened, so that the water surface is matched with the water surface to descend, the garbage on the water surface enters the conveying cavity 14 through the triangular collection filter frame 17 and the filter frame cavity 86, and the garbage is automatically collected through the water flow direction and the water surface descending; the lower conveying shaft 89 rotates to drive the conveying belt 13 to rotate, so that the garbage entering the conveying cavity 14 is conveyed upwards through the conveying filter plate 15 to enter the compression cavity 11 through the garbage through cavity 12, and the garbage is separated from river water and transferred at the same time; the front-side forward and reverse rotation bevel gear 60 rotates to drive the front-side forward and reverse rotation gear 61 to rotate and simultaneously drive the rear-side forward and reverse rotation bevel gear 60 to rotate reversely through the transmission bevel gear 62, the rear-side forward and reverse rotation bevel gear 60 rotates reversely to drive the rear-side forward and reverse rotation gear 61 to rotate reversely, since the forward and reverse rotation electromagnet 66 is not started, the meshing gear 68 and the front-side forward and reverse rotation gear 61 are started, the front-side forward and reverse rotation gear 61 rotates to drive the spline shaft 69 and the forward and reverse rotation shaft 71 to rotate through the meshing gear 68, so that the lifting transmission shaft 73 rotates through the third bevel gear 72 and the fourth bevel gear 74, the lifting transmission shaft 73 rotates to drive the sleeve power shaft 82 to rotate through the lifting transmission belt 80, the sleeve power shaft 82 rotates to drive the sleeve gear 84 to rotate through the sleeve transmission gear 79 and simultaneously drive the rear-side sleeve 85 to rotate through the sleeve transmission, the sleeve gear 84 rotates to drive the front lifting shaft 83 and the front lifting box 49 to move downwards through the front sleeve 85, the rear lifting box 49 moves upwards, the friction wheel 48 is driven to rotate through the friction strip 45, the friction wheel shaft 47 is driven to rotate against the elastic force of the pressure plate return spring 50 by the one-way bearing 43, thereby driving the rear compression plate 51 to rotate to be completely positioned in the rear lifting box cavity 24, avoiding collision with the front compression plate 51, blocking the compression limiting block 40 by the limiting baffle 41 when the front compression plate 51 moves downwards, thereby preventing the front compression plate 51 from reversely rotating, completing the compression of the garbage by matching the downward movement of the front compression plate 51, after the left lifting box 49 moves upward until the friction wheel 48 is separated from the friction strip 45, the friction wheel shaft 47 reversely rotates under the elastic force of the pressure plate return spring 50, thereby driving the compression plate 51 to rotate reversely and reset, and the garbage continuously enters the compression cavity 11 through the garbage through cavity 12 and then falls to the upper side of the front compression plate 51; when the liquid levels on the left side and the right side of the main body box 10 are level, the baffle electromagnet 18 is just closed, the baffle 21 is closed, the filter frame rotating shaft 59 rotates reversely under the elastic force action of the filter frame return spring 57, the triangular collection filter frame 17 is closed, and the liquid level on the right side of the main body box 10 starts to rise again; when the liquid level contacts the contact sensor 16 again, the above process is repeated, the contact sensor 16 sends out a double-number signal to enable the forward and reverse rotation electromagnet 66 to be started, the magnetic rotation plate 67 overcomes the pulling force of the magnetic rotation plate spring 65 to move backwards under the action of the repulsive force between the magnetic rotation plate 67 and the forward and reverse rotation electromagnet 66, the spline shaft 69 drives the meshing gear 68 to move backwards to be meshed with the rear forward and reverse rotation gear 61, the meshing gear 68 starts to rotate backwards, the front lifting box 49 moves upwards, the rear lifting box 49 moves downwards to complete the compression of the garbage, and the collection and compression of the garbage on the water surface can be completed while the hydroelectric power generation is performed through the river channel.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a take hydraulic power generation facility for river course of refuse collection compression function, includes the main part case, its characterized in that: the lower end face of the main box is fixedly connected with a fixing pile, a left-right through power generation cavity is arranged in the main box, a conveying cavity is arranged on the upper side of the power generation cavity, a filter frame cavity is communicated and arranged on the right side of the conveying cavity, a garbage through cavity is communicated and arranged at the tail end of the upper side of the left end face of the conveying cavity leftwards, a compression cavity is communicated and arranged on the left side of the garbage through cavity, lifting box cavities are symmetrically arranged on the front side and the rear side of the compression cavity, a power steering cavity is arranged on the lower side of the compression cavity, a forward and reverse rotation cavity is arranged on the rear side of the power steering cavity, a meshing cavity is communicated and arranged on the right side of the forward and reverse rotation cavity, a contact sensor positioned between the filter frame cavity and the garbage through cavity is fixedly connected in the right end wall of the main box, a lifting box is connected, the right end wall of the friction wheel cavity is connected with a friction wheel shaft which extends leftwards into the compression limiting cavity and rightwards to the outside in a rotating fit mode, the friction wheel shaft is fixedly connected with a one-way bearing which is located in the friction wheel cavity, the one-way bearing is connected with a friction wheel in a rotating fit mode, and the outer end wall of the lifting box cavity is fixedly connected with a friction strip which can be abutted against the friction wheel.

2. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the lift case outside is equipped with the compression board, be equipped with the outside lift case rotation chamber of opening in the compression board, the friction shaft extend right to with the lift case rotates chamber right-hand member wall fixed connection, compress spacing chamber outer end wall fixedly connected with compression limit baffle, the terminal fixedly connected with in friction shaft outer terminal surface left side can with the compression stopper of compression limit baffle butt, and work as when the compression board is in the horizontality, the terminal surface just with compression limit baffle up end butt is spacing under the compression stopper, friction shaft left end face with fixedly connected with clamp plate reset spring, both sides between the spacing chamber left end wall of compression lift case chamber upside intercommunication is equipped with sleeve transmission chamber, lift case up end fixedly connected with upwards extends and runs through sleeve transmission chamber to external lift axle.

3. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the sleeve that symmetry set up around upper end wall normal running fit is connected with in the sleeve transmission intracavity, the ascending and descending epaxial extension runs through the sleeve and with sleeve screw-thread fit connects, sleeve transmission chamber upside is equipped with the lift pulley chamber that the rear side extends left, lift pulley chamber lower extreme wall normal running fit is connected with downwardly extending to sleeve transmission intracavity and upwards extend to the sleeve power shaft in the lift pulley intracavity, fixedly connected with is located on the sleeve power shaft sleeve drive gear in the sleeve transmission intracavity, the front side fixedly connected with on the sleeve with the sleeve gear meshing's sleeve gear, sleeve power shaft and rear side power fit is connected with between the sleeve and is located the sleeve drive belt in the sleeve transmission intracavity.

4. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the power generation device is characterized in that a fan blade box is fixedly connected to the upper end wall of the power generation cavity, a power generation belt wheel cavity extending upwards into the main body box is arranged in the fan blade box, a power generator fixedly connected with the main body box is arranged on the right side of the power generation belt wheel cavity, a power generation rotating shaft extending leftwards and penetrating through the power generation belt wheel cavity to the power steering cavity is fixedly connected to the left end face of the power generator, a fan blade shaft extending rightwards into the power generation cavity is connected to the left end wall of the power generation belt wheel cavity in a rotating fit manner, fan blades are fixedly connected to the right end of the fan blade shaft, a power generation driving belt positioned in the power generation belt wheel cavity is connected between the fan blade shaft and the power generation rotating shaft in a power fit manner, a baffle plate cavity positioned on the right side of the conveying cavity is communicated to the upper side of the power generation cavity, a baffle plate, and a baffle electromagnet is fixedly connected in the upper end wall of the baffle cavity.

5. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the power steering cavity front side is provided with a right-extending conveying belt wheel cavity, the conveying belt wheel cavity front side is provided with a filter frame belt wheel cavity, the conveying shaft which extends backwards into the conveying cavity is connected in the conveying cavity front end wall in a vertically symmetrical rotating fit manner, the conveying shaft which extends forwards into the conveying belt wheel cavity is arranged at the lower side, the conveying belt which is positioned in the conveying cavity is connected between the conveying shafts in a power fit manner, the outer end surface of the conveying belt is fixedly connected with a plurality of conveying filter plates which are arranged at equal intervals, a filter frame transmission cavity is arranged between the filter frame belt wheel cavity and the filter frame cavity, the filter frame cavity front end wall is connected in a rotating fit manner with a filter frame rotating shaft which extends forwards into the filter frame transmission cavity and extends backwards into the filter frame cavity, the filter frame rotating shaft rear end is fixedly connected with a triangular collecting filter frame which has an initial-state downward opening and a leftward opening, and the filter frame rotating shaft front end is fixedly, and a filter frame return spring is fixedly connected between the front end surface of the filter frame rotating shaft and the front end wall of the filter frame transmission cavity.

6. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the power steering cavity is internally provided with a power distribution shaft which is in rotary fit connection with the front end wall of the power steering cavity, extends forwards to penetrate through the conveyor belt wheel cavity and extends backwards to the filter frame belt wheel cavity, the front side of the power steering cavity is in power fit connection with the conveyor belt which is positioned in the conveyor belt wheel cavity, the front end wall of the filter frame transmission cavity is in rotary fit connection with the filter frame transmission shaft which extends forwards to the filter frame belt wheel cavity and extends backwards to the filter frame transmission cavity, the tail end of the rear side of the filter frame transmission shaft is fixedly connected with a filter frame transmission gear which can be meshed with the half gear, the filter frame transmission shaft is in power fit connection with the power distribution shaft and is positioned in the filter frame belt wheel cavity, the tail end of the left side of the power generation rotating shaft is fixedly connected with a first bevel gear, and the power steering cavity is internally provided with a second bevel gear which is fixedly connected with the power distribution shaft and meshed with.

7. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: the front and back of the cavity are symmetrically provided with forward and reverse gears which are in matched connection with the power distribution shaft in a rotating mode, the inner end face of each forward and reverse gear is fixedly connected with a forward and reverse bevel gear, the forward and reverse bevel gear is fixedly connected with the power distribution shaft at the front side, the forward and reverse bevel gear is in matched connection with the power distribution shaft at the rear side, the left end wall of the cavity is connected with a transmission bevel gear shaft in a rotating mode, the transmission bevel gear shaft extends rightwards into the cavity in the forward and reverse mode, and the tail end of the right side of the transmission bevel gear shaft is fixedly connected with a transmission bevel gear meshed.

8. The hydraulic power generation device with the garbage collection and compression functions for the riverway according to claim 1, is characterized in that: a bevel gear cavity is arranged at the rear side of the meshing cavity, a forward rotating shaft and a reverse rotating shaft which extend forwards into the meshing cavity and extend backwards into the bevel gear cavity are connected to the rear end wall of the meshing cavity in a rotationally matched manner, a spline shaft is connected to the front end of the forward rotating shaft and the reverse rotating shaft in a splined manner, a magnetic rotating plate is connected to the front end of the sleeve transmission gear in a rotationally matched manner, a forward rotating electromagnet and a reverse rotating electromagnet are fixedly connected to the front end wall of the meshing cavity, a magnetic rotating plate spring is fixedly connected between the front end surface of the magnetic rotating plate and the front end wall of the meshing cavity, a meshing gear capable of meshing with the forward rotating gear and the reverse rotating gear is fixedly connected to the spline shaft, a third bevel gear is fixedly connected to the rear end of the forward rotating shaft and the reverse rotating shaft, a lifting transmission shaft which extends upwards into the lifting belt wheel cavity is connected to the lower end, and a lifting transmission belt positioned in the lifting belt wheel cavity is connected between the lifting transmission shaft and the sleeve power shaft in a power fit manner.