Electric power generation anti-seepage device
Technical Field
The invention relates to the technical field of electric power anti-seepage treatment, in particular to an electric power generation anti-seepage device.
Background
In the thermal power generation process, coal ash and coal cinder are wastes generated by boiler combustion, wherein the coal cinder can be reused, the coal ash contains substances such as sulfide and NOx which can cause continuous damage to the ecological environment, the existing treatment of boiler combustion products is generally adopted, open-air storage is established in remote areas, harmful substances in ash materials are prevented from penetrating into the underground and polluting underground water by tamping the ground and paving an impermeable layer, but the impermeable treatment method for the ash materials has the following defects: 1. the outdoor storage is easily affected by windy weather, ash can be blown out along with wind to further pollute the environment, 2, the ash is stored on the ground, so that the storage amount of a unit area can be reduced, the area of an ash yard is increased, and 3, coal ash and coal cinder are stored in a mixed mode, wherein the coal cinder can be reused, and resources are wasted due to mixed discarding, so that the electric power generation anti-seepage device is provided.
Disclosure of Invention
The invention aims to provide an electric power generation anti-seepage device to solve the problems in the background technology.
In order to achieve the purpose, the invention provides the following technical scheme:
the utility model provides an electric power generation anti-seepage device, includes tower casing, slag coal ash conveying system, coal ash extrusion system, control electronic box and hydraulic control system, slag coal ash conveying system sets up the outside at the tower casing, coal ash extrusion system cover is established inside the tower casing, the control electronic box sets up the bottom outside at the tower casing, slag coal ash conveying system includes that wind inhales transports motor, slag coal ash separator, coal ash turnover ware and slag and temporarily preserves the case, slag coal ash separator includes separation casing and toper stripper, the toper stripper includes the pivot and peels off the blading, it establishes in the pivot to peel off the blading, be equipped with the locating rack in the separation casing, be equipped with the gyration cover on the locating rack, the toper stripper is installed in the separation casing through the cooperation of pivot and gyration cover, the toper stripper cover is established in the separation casing, the separation cover passes through the slag pipe and the connection of slag temporary storage box, coal ash turnover ware is including turnover cover and wind dust filter, the turnover cover passes through the coal ash pipe and is connected with slag coal ash separator, coal ash extrusion system carries the group including storing up coal ash jar, spiral unloader group, coal ash extrusion group and blanking, spiral unloader group is including spiral cover, screw conveyer and driving motor, top one side of spiral cover is equipped with the feed inlet, spiral cover bottom one side is equipped with arranges the material pipe, the both ends of spiral cover are equipped with the gyration hole, screw conveyer passes through the cooperation of drive shaft and gyration hole and installs in the spiral cover, the bottom cover of drive shaft is equipped with driven pulley, driving motor's bottom cover is equipped with driving pulley, driven pulley passes through the belt and is connected with driving pulley, coal ash extrusion group is including extrusion oil cylinder, coal ash extrusion oil cylinder, The extrusion pipe device, the discharging oil cylinder and the solar power generation assembly are combined, the extrusion pipe device comprises a compression sleeve, a pressure gauge and a bottom sealing plate, the pressure device is provided with a push rod and a pressure plate, the pressure plate is sleeved in the compression sleeve, a support beam is arranged in the tower cover, the extrusion oil cylinder is arranged on the support beam and is connected with one end of the push rod through the push shaft, the heater is arranged in the compression sleeve, the bottom of the compression sleeve is sleeved with a discharging oil cylinder base, the bottom of the discharging oil cylinder base is provided with a connecting pin, the discharging oil cylinder base is connected with the bottom sealing plate through a connecting pin, the discharging oil cylinder is arranged on one side of the discharging oil cylinder base, one end of the discharging oil cylinder is connected with a push rod on the bottom sealing plate, the blanking conveying group comprises a transfer motor and a belt conveyor, the one end of transporting the motor is connected with the commentaries on classics rod of belt feeder, be equipped with control button on the control electronic box.
As a preferred embodiment of the present invention, a water passage is provided in the push rod, a water storage tank is provided at one side of the compression sleeve, and the water passage is connected to the water storage tank through a pipeline.
In a preferred embodiment of the present invention, a steam exhaust pipe is provided at one side of the compression sleeve.
In a preferred embodiment of the present invention, the discharge pipe is connected to one side of the compression sleeve through a pipe.
In a preferred embodiment of the present invention, a protective cover is provided outside the driven pulley and the driving pulley.
As a preferred embodiment of the present invention, a circular hole is formed in the bottom of the coal ash storage tank, and one end of the spiral unloader group is mounted at the bottom of the coal ash storage tank through the cooperation of the spiral cover and the circular hole.
In a preferred embodiment of the present invention, the solar power generation assembly includes a solar panel and a battery, the heater is connected to the battery through a wire, and the solar panel is connected to the battery through a wire.
As a preferred embodiment of the present invention, the hydraulic control system includes a hydraulic pump and a hydraulic oil tank, and the hydraulic oil tank is connected to the squeeze cylinder and the discharge cylinder through a pipeline.
As a preferred embodiment of the present invention, a cinder baffle is disposed on the rotating shaft, and a feeding pipe is disposed at the bottom of the separation cover.
As a preferred embodiment of the present invention, the control button includes a coal cinder conveying button, a blanking button, a compression button, a heating button, an opening button and a transfer button, and the control button is connected to the air suction transfer motor, the driving motor, the transfer motor, the extrusion cylinder and the discharge cylinder through wires.
Compared with the prior art, the invention has the beneficial effects that:
1. by adopting the tower type building, the ash is stored vertically, the storage capacity of the ash in unit area is improved, and dust generated by windy weather on the ash is prevented from polluting air.
2. The coal ash extrusion molding system is used for carrying out water-soluble mixed extrusion molding on the ash material, drying the ash material into a molded ash material through a solar power supply heater, further compressing the volume of the ash material and increasing the storage amount of the ash material.
3. The slag-coal ash separator in the slag-coal ash conveying system can discharge slag separately for storage and reuse.
Drawings
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic view of the ash extrusion system of the present invention;
FIG. 3 is a schematic structural view of a slag coal ash delivery system of the present invention;
FIG. 4 is a schematic structural view of a slag-coal ash separator of the present invention;
FIG. 5 is a schematic view of the construction of the conical stripper of the present invention;
FIG. 6 is a schematic illustration of the configuration of the coal ash epicyclic of the present invention;
FIG. 7 is a schematic view of the construction of the spiral feeder group of the present invention;
FIG. 8 is a schematic structural view of a coal ash extrusion group of the present invention;
in the figure: 1-tower cover, 2-slag coal ash conveying system, 3-coal ash extrusion forming system, 4-control electric box, 5-wind suction transfer motor, 6-slag coal ash separator, 7-coal ash turnover device, 8-slag temporary storage box, 9-separation cover, 10-conical stripper, 11-slag pipe, 12-turnover cover, 13-wind dust filter plate, 14-rotating shaft, 15-stripping blade group, 16-positioning frame, 17-turnover sleeve, 18-coal ash storage tank, 19-spiral blanking machine group, 20-coal ash extrusion group, 21-blanking conveying group, 22-spiral cover, 23-spiral conveyor, 24-driving motor, 25-discharging pipe, 26-driving shaft, 27-driving pulley, 28-driven pulley, 28-wind suction transfer motor, 6-slag coal ash separator, 7-coal ash turnover device, 8-slag temporary storage tank, 9-coal ash extrusion forming tank, 20-coal ash extrusion forming group, 29-extrusion oil cylinder, 30-extrusion pipe device, 31-discharge oil cylinder, 32-compression sleeve, 33-pressure device, 34-first push rod, 35-pressure plate, 36-solar power generation combination, 37-discharge oil cylinder base, 38-connecting pin, 39-bottom sealing plate, 40-second push rod, 41-supporting beam, 42-push shaft, 43-transfer motor, 44-belt conveyor, 45-rotating rod, 46-water channel, 47-water storage tank, 48-steam exhaust pipe, 49-hydraulic control system, 50-cinder baffle and 51-heater.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-8, the present invention provides a technical solution:
the utility model provides an electric power generation anti-seepage device, includes tower casing 1, slag coal ash conveying system 2, coal ash extrusion system 3, control electronic box 4 and hydraulic control system 49, slag coal ash conveying system 2 sets up the outside at tower casing 1, 3 covers of coal ash extrusion system establish inside tower casing 1, control electronic box 4 sets up the bottom outside at tower casing 1, slag coal ash conveying system 2 includes that wind inhales transportation motor 5, slag coal ash separator 6, coal ash turnover 7 and slag temporary storage box 8, slag coal ash separator 6 includes separation cover 9 and toper stripper 10, toper stripper 10 includes pivot 14 and peels off blading 15, it establishes on pivot 14 to peel off blading 15 cover, be equipped with locating rack 16 in the separation cover 9, be equipped with gyration cover 17 on the locating rack 16, toper stripper 10 is installed in separation cover 9 through the cooperation of pivot 14 and gyration cover 17, the conical stripper 10 is sleeved in the separation cover 9, the separation cover 9 is connected with a slag temporary storage box 8 through a slag pipe 11, the coal ash turnover device 7 comprises a turnover cover 12 and an air dust filter plate 13, the turnover cover 12 is connected with a slag coal ash separator 6 through a coal ash pipe, the coal ash extrusion forming system 3 comprises a coal ash storage tank 18, a spiral unloader group 19, a coal ash extrusion group 20 and a blanking conveying group 21, the spiral unloader group 19 comprises a spiral cover 22, a spiral conveyor 23 and a driving motor 24, a feed inlet is arranged on one side of the top of the spiral cover 22, a discharge pipe 25 is arranged on one side of the bottom of the spiral cover 22, rotary holes are arranged at two ends of the spiral cover 22, the spiral conveyor 23 is arranged in the spiral cover 22 through the matching of the driving shaft 26 and the rotary holes, a driving belt pulley 27 is sleeved at the bottom of the driving shaft 26, a driven belt pulley 28 is sleeved at the bottom of the driving, the driving pulley 27 is connected with the driven pulley 28 through a belt, the coal ash extrusion group 20 comprises an extrusion oil cylinder 29, an extrusion pipe device 30, a discharging oil cylinder 31 and a solar power generation combination 36, the extrusion pipe device 30 comprises a compression sleeve 32, a pressure device 33 and a bottom sealing plate 39, a first push rod 34 and a pressure plate 35 are arranged on the pressure device 33, the pressure plate 35 is sleeved in the compression sleeve 32, a support beam 41 is arranged in the tower cover 1, the extrusion oil cylinder 29 is installed on the support beam 41 and connected with one end of the first push rod 34 through a push shaft 42, a heater 51 is arranged inside the compression sleeve 32, a discharging oil cylinder seat 37 is sleeved at the bottom of the compression sleeve 32, a connecting pin 38 is arranged at the bottom of the discharging oil cylinder seat 37, the discharging oil cylinder seat 37 is connected with the bottom sealing plate 39 through the connecting pin 38, the discharging oil cylinder 31 is installed at one side of the discharging oil cylinder seat 37, one end of the discharging oil cylinder 31 is connected with a second push rod 40 on the, the blanking conveying group 21 comprises a transfer motor 43 and a belt conveyor 44, one end of the transfer motor 43 is connected with a transfer roller 45 of the belt conveyor 44, and a control button is arranged on the control electric box 4.
In a preferred embodiment of the present invention, a water passage 46 is provided in the first push rod 34, a water storage tank 47 is provided at one side of the compression sleeve 32, and the water passage 46 is connected to the water storage tank 47 through a pipeline.
In a preferred embodiment of the present invention, the compression sleeve 32 is provided with a steam exhaust pipe 48 at one side thereof.
In a preferred embodiment of the present invention, the discharge pipe 25 is connected to one side of the compression sleeve 32 through a pipe.
In a preferred embodiment of the present invention, the driving pulley 27 and the driven pulley 28 are externally provided with a protective cover.
In a preferred embodiment of the present invention, the bottom of the coal ash storage tank 18 is provided with a circular hole, and one end of the spiral blanking unit 19 is mounted at the bottom of the coal ash storage tank 18 through the cooperation of the spiral cover 22 and the circular hole.
In a preferred embodiment of the present invention, the solar power generation assembly 36 comprises a solar panel and a battery, the heater 51 is connected to the battery through a wire, and the solar panel is connected to the battery through a wire.
In a preferred embodiment of the present invention, the hydraulic control system 49 includes a hydraulic pump and a hydraulic oil tank, and the hydraulic oil tank is connected to the squeeze cylinder 29 and the dump cylinder 31 through a pipeline.
In a preferred embodiment of the present invention, a cinder baffle 50 is provided on the rotating shaft 14, and a feeding pipe is provided at the bottom of the separation hood 9.
In a preferred embodiment of the present invention, the control buttons include a coal cinder conveying button, a blanking button, a compression button, a heating button, an opening button and a transfer button, and the control buttons are connected to the air suction transfer motor 5, the driving motor 24, the transfer motor 43, the extrusion cylinder 29 and the discharge cylinder 31 through wires.
The working principle is as follows: firstly, the control electric box 4 is connected to an external power supply, and the external power supply provides main electric energy for the electric power generation anti-seepage device. The feeding pipe at the bottom of the separation cover 9 is placed into an engineering wagon box with coal ash and coal cinder, a coal cinder and coal ash conveying button is manually pressed, the air suction transfer motor 5 is started to generate negative pressure suction effect, the coal cinder and coal ash mixed material enters the furnace cinder and coal ash separator 6 through the feeding pipe, the stripping blade group 15 starts to rotate under the action of wind power, the coal cinder enters the furnace cinder temporary storage box 8 through a pipeline under the rotation impact of the stripping blade group 15, the furnace cinder and coal ash separator in the furnace cinder and coal ash conveying system can independently discharge furnace cinder for storage and reuse, the coal ash enters the coal ash turnover device 7 through a pipeline under the filtering effect of the coal cinder baffle plate 50, the coal ash falls into the coal ash storage tank 18 through the filtering effect of the wind dust filter plate 13, so that the ash is vertically stored, the storage capacity of the ash in unit area is improved, and dust pollution to the ash in strong wind weather is avoided, at the moment, a blanking button is manually pressed, a driving motor 24 starts a driven belt wheel 28 to rotate, a driving belt wheel 27 is driven to rotate through a belt, a screw conveyor 23 rotates to send coal ash at the bottom of a coal ash storage tank 18 downwards into a discharge pipe 25 and into a compression sleeve 32, a compression button is manually pressed, a hydraulic control system 49 works, a hydraulic pump supplies oil to an extrusion oil cylinder 29, the extrusion oil cylinder 29 is pushed to move downwards, an extrusion pipe device 30 moves downwards, a water storage tank 47 feeds water into a water passing channel 46 through a pipeline and sprays wet coal ash into the compression sleeve 32 through a water spraying hole in a first push rod 34, a pressure plate 35 starts to extrude the coal ash, the coal ash is subjected to water-soluble mixing extrusion molding, the formed coal ash is dried into a formed coal ash through a solar power supply heater 51, the volume of the coal ash is further compressed, the storage amount of the coal ash is increased, a heating button is manually pressed, a solar, the heater 51 generates heat to start drying the formed coal ash, then the opening button is manually pressed, the discharging oil cylinder 31 moves for return stroke, the second push rod 40 rotates clockwise, the bottom sealing plate 39 is opened, the formed coal ash falls onto the belt conveyor 44 under the continuous pushing of the pressure plate 35, then the transfer motor 43 is manually pressed to start and drive the rotary rod 45 to rotate, the formed coal ash is conveyed to the next storage place by the belt conveyor 44, and the storage capacity of the ash in unit area is further improved.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.