CN116375206B - Aged garbage leachate treatment device and method - Google Patents

Abstract

The invention belongs to the technical field of garbage treatment, and particularly relates to an aged garbage leachate treatment device and a method thereof, comprising a sub-filtering device, an eduction tube, a mixing drum and an oxidation strengthening treatment device, wherein the sub-filtering device comprises a central drum and a plurality of sub-filtering drums which are arranged on the outer wall of the central drum in an annular array manner, a nanofiltration membrane for separating ammonia nitrogen-containing filtrate is embedded between the central drum and the sub-filtering drums, one end of a bottom ring tube is connected with a liquid-separating tube connected with an inlet of the anaerobic ammonia oxidation treatment device, the output end of the anaerobic ammonia oxidation treatment device is connected with the eduction tube for guiding the filtrate subjected to anaerobic ammonia oxidation treatment into the mixing drum, and one side of the bottom of the mixing drum is connected with a mixed liquid outlet for guiding the mixed liquid into the oxidation strengthening treatment device. The invention can reduce the influence of COD on the denitrification process, and ensure the denitrification efficiency when the invention has the advantages of low carbon, energy saving and denitrification.

Description

Aged garbage leachate treatment device and method

Technical Field

The invention belongs to the technical field of garbage treatment, and particularly relates to an aged garbage leachate treatment device and method.

Background

The old landfill leachate often has the following two characteristics: 1. the ammonia nitrogen concentration is high and reaches 2000-3500 mg/L; 2. the COD concentration is relatively low and is 2000-4000 mg/L, and most of the COD is humic acid which is difficult to biodegrade; if the conventional nitrification-denitrification process is used, COD in the aged garbage percolate is often the COD which is difficult to biodegrade, and carbon sources required by denitrification are added additionally, 1000mg/L ammonia nitrogen is added, the consumption of the carbon sources is up to COD above 5000mg/L, the adding cost of the carbon sources is high, and a large amount of sludge is generated. The minimum carbon energy-saving biological denitrification technology is anaerobic ammonia oxidation, ammonia nitrogen can be removed almost without a carbon source, and the method has the advantages of low aeration energy consumption, low carbon and the like. However, the high concentration of the difficultly biodegradable COD and other impurities in the percolate can cause stronger interference to the rhodobacter anaerobically ammoxidation.

Disclosure of Invention

The invention aims to provide an aged garbage leachate treatment device and a method thereof, which can reduce the influence of COD on the denitrification process, so that the device can ensure the denitrification efficiency when having the advantages of low carbon, energy saving and denitrification.

The technical scheme adopted by the invention is as follows:

an aged landfill leachate treatment device which is characterized in that: the device comprises a sub-filtering device, a delivery pipe, a mixing drum and an oxidation strengthening treatment device, wherein the sub-filtering device comprises a central drum and a plurality of sub-filtering drums which are arranged on the outer wall of the central drum in an annular array manner, the sub-filtering drums are communicated with the central drum and are used for collecting filtrate containing high-concentration ammonia nitrogen components separated from landfill leachate, and nanofiltration membranes used for separating ammonia nitrogen-containing filtrate are arranged between the central drum and the sub-filtering drums in an embedded manner;

the filter cartridges are connected with a bottom ring pipe through a bottom pipeline, one end of the bottom ring pipe is connected with a liquid separating pipe connected with an inlet of the anaerobic ammonia oxidation treatment device, and a valve III for controlling the circulation inside the liquid separating pipe is fixedly arranged in the middle of the liquid separating pipe; the bottom of the middle-arranged barrel is connected with a liquid outlet pipe connected with the top of the mixing barrel, one end of the liquid outlet pipe is fixedly provided with a valve II for controlling the circulation inside the liquid outlet pipe, the output end of the anaerobic ammonia oxidation treatment device is connected with a delivery pipe for guiding filtrate subjected to anaerobic ammonia oxidation treatment into the mixing barrel, one side of the bottom of the mixing barrel is connected with a mixed liquid outlet pipe for guiding mixed liquid into the oxidation strengthening treatment device, two ends of the mixed liquid outlet pipe are provided with a power pump for extracting the mixed liquid and a valve IV for controlling the circulation inside the mixed liquid outlet pipe, and an inner barrel body is fixedly arranged in the mixing barrel;

the outer wall of the mixing drum is fixedly provided with a plurality of outer guide frames in an annular array manner, the inner sides of the outer guide frames are respectively and slidably assembled with a climbing machine, and the inner sides of the climbing machines are respectively and fixedly provided with a magnet;

the inner wall of the inner cylinder body is fixedly provided with an inner guide frame at a position close to the outer guide frame, an inner net rack is assembled in the inner cylinder body in a lifting mode, end metal sliding blocks are fixedly arranged on the edge of the inner net rack in an annular array mode, and the end metal sliding blocks are slidably arranged in the inner guide frame;

the upper surface of the inner net rack is rotatably assembled with a turbine blade rack, and blades with inclined angles are fixedly arranged on the inner side of the turbine blade rack in an annular array manner;

the lower surface of the circle center of the turbine blade frame is fixedly provided with a bottom disc, the bottom disc is arranged below the circle center of the inner net frame, the circle center of the inner net frame is fixedly provided with a limit stop in an annular array manner, and the outer wall of the edge of the bottom disc is fixedly provided with a bulge in an array manner;

the top of the middle-arranged barrel is integrally and fixedly provided with a transition barrel, the top end of the transition barrel is fixedly connected with a liquid inlet pipe for guiding garbage percolate, and one end of the liquid inlet pipe is provided with a valve I for controlling the circulation inside the liquid inlet pipe; the top of each sub-filter cylinder is fixedly connected with a pressurizing pipe, the top of the interior of the pressurizing pipe is movably provided with a piston, a spring is arranged in the pressurizing pipe and below the piston, the top of the pressurizing pipe is fixedly connected with a branch pipe, and the tail end of each branch pipe is connected with a liquid inlet pipe in an inclined tee way;

the utility model discloses a filter device, including branch filter device, including the filter device, divide the filter device's inside equipment to have and be used for accelerating the separation helping hand subassembly that contains ammonia nitrogen filtrate, separate helping hand subassembly includes and constitutes movable spliced relation with put the section of thick bamboo and wear the pole, put the outer wall of putting the section of thick bamboo and install the cylinder that is used for controlling to wear the pole and go up and down to remove, wear the end of pole and be arranged in put the inside fixed mounting of section of thick bamboo in, just the bottom of inner frame rotates the group and has the helping hand dish, a plurality of through-holes have been seted up to the annular array in edge of helping hand dish, just helping hand dish lower surface and the position department that corresponds the through-hole all is provided with empty pipe, the inside of each through-hole is all fixed and is provided with the baffle plate, and the inside movable mounting of empty pipe has interior annular plate, the surface edge of inner ring plate is provided with the stores pylon that is used for hanging the baffle plate, and the bottom of each empty pipe all is fixedly connected with inclined bearing plate, at the in-process that the helping hand dish goes up, and the through-hole mediation can give inclined bearing plate pressure and drive helping hand dish rotation at the in-process that the through-hole is passed through to the rubbish infiltration.

The height dimension of the middle-arranged barrel is larger than that of the sub-filtering barrel, and the volume of the inner space of the pressurizing pipe is larger than that of the whole branch pipe.

The inner diameter of the inner ring plate is smaller than the diameter of the baffle plate, and the inclined bearing plate and the stirring rod are arranged alternately.

The tail end of the delivery pipe is fixedly connected with an outer ring pipe, the outer ring pipe is fixedly arranged outside the mixing drum, and the inner side of the outer ring pipe is fixedly connected with an inclined inlet pipe in an annular array mode.

The tail end of the inclined inlet pipe is obliquely inserted into the inner cylinder body.

A treatment method of aged garbage leachate comprises the following specific steps:

s1: preprocessing old landfill leachate in a middle-placed cylinder to separate filtrate containing high-concentration ammonia nitrogen components, temporarily storing the separated filtrate in a filter cylinder, and compressing organic matters which are difficult to biodegrade and other suspended and colloidal impurities in concentrated liquid;

s2: after the garbage infiltration is injected into the middle cylinder, stopping the injection process, simultaneously starting the air cylinder to drive the booster disc to reciprocate, wherein each through hole is blocked by the inner annular plate in the descending process of the booster disc, so that the booster disc can give downward pressure to the garbage infiltration liquid, the filtering work is quickened, in the ascending process of the booster disc, the through holes are dredged, the garbage infiltration liquid can give pressure to the inclined bearing plate and drive the booster disc to rotate in the passing process of the through holes, and the stirring rod is matched to realize the stirring effect, so that the garbage infiltration liquid at other positions is stirred to the nanofiltration membrane;

s3: adopting an anaerobic ammonia oxidation treatment device to remove total nitrogen in nanofiltration membrane filtrate, and opening a valve III to lead filtrate in each sub-filter cartridge into the anaerobic ammonia oxidation treatment device for anaerobic ammonia oxidation treatment;

s4: introducing filtrate after anaerobic ammonia oxidation denitrification treatment into the inner cylinder body through a delivery pipe, introducing concentrated solution which is originally positioned in the middle cylinder into the inner cylinder body through a liquid outlet pipe, and remixing the filtrate and the concentrated solution at the moment, wherein total nitrogen in the mixed solution is removed by an anaerobic ammonia oxidation treatment device;

s5: and opening a power pump and a valve IV, and introducing the mixed solution into the oxidation strengthening treatment device for biochemical strengthening treatment to further remove the total nitrogen in COD and water.

The invention has the technical effects that:

the invention firstly carries out pretreatment on the aged garbage leachate, separates filtrate containing high-concentration ammonia nitrogen components, and the filtrate filtered by the nanofiltration membrane contains high-concentration ammonia nitrogen, can adopt a high-efficiency anaerobic ammonia oxidation treatment device to remove ammonia nitrogen and total nitrogen in the water, and is mixed with the concentrated water of the nanofiltration membrane after anaerobic ammonia oxidation denitrification treatment.

In the self-cleaning operation of the nanofiltration membrane, the filtrate reversely passes through the nanofiltration membrane, and particles which are originally blocked in gaps of the nanofiltration membrane are washed out, so that the self-cleaning effect of the nanofiltration membrane is achieved, the cleaning operation of the nanofiltration membrane can be realized, the function of the equipment is increased, the long-term use of the nanofiltration membrane can be ensured, the operation of manually and periodically disassembling the equipment to clean the nanofiltration membrane is omitted, in addition, the cleaning operation of the nanofiltration membrane is realized without additional electric equipment, only the valve I and the valve III are needed to be respectively closed, the cleaning operation of the nanofiltration membrane is completed by virtue of the process of injecting garbage percolate, and the investment of other electric equipment is omitted while the equipment is simplified.

According to the invention, after a certain volume of landfill leachate is injected into the middle cylinder, the injection process is stopped, and the cylinder is started to drive the power-assisted disc to reciprocate, so that the filtration speed of the landfill leachate can be accelerated in the reciprocating elevating process of the power-assisted disc, and the landfill leachate at different positions can be driven to continuously approach the nanofiltration membrane, so that the landfill leachate can be fully contacted with the nanofiltration membrane, and the filtration efficiency of the landfill leachate is indirectly improved.

According to the invention, as the tail end of the inclined inlet pipe is obliquely inserted into the inner cylinder body, a certain flow effect is generated between filtrate and concentrated liquid in the mixing cylinder after the filtrate enters the inner cylinder body, and the internal mixed liquid can generate a vortex-like flow process under the impact of tangential water flow, so that the mixing effect of the filtrate and the concentrated liquid is improved.

In order not to influence the effect of pumping mixed liquid by the power pump, at the moment, each climbing machine is started to enable the magnet to climb along the outer guide frame, the inner guide frame also climbs inside the inner cylinder body under the action of magnetic force, the turbine blade frame and the inner net frame simultaneously rotate relatively, blades in the turbine blade frame can block gaps of the inner net frame, so that the turbine blade frame and the inner net frame can drive more sludge to move upwards when climbing, the problem of sludge deposition is solved, the problem of blocking the power pump caused by the sludge deposition is solved, and the work load of the power pump is reduced.

Drawings

FIG. 1 is a combined schematic diagram of a processing apparatus provided by an embodiment of the present invention;

FIG. 2 is a schematic diagram of a combination of a filter and a mixing drum according to an embodiment of the present invention;

FIG. 3 is a schematic diagram showing a combination of an anaerobic ammonium oxidation treatment device, a mixing drum and an oxidation strengthening treatment device according to an embodiment of the present invention;

FIG. 4 is an assembled cross-sectional view of a split filter device and a split assist assembly according to an embodiment of the present invention;

FIG. 5 is a block diagram of a separation assist assembly provided by an embodiment of the present invention;

FIG. 6 is an exploded view of an assembly of a power disc with an inner ring plate provided by an embodiment of the present invention;

FIG. 7 is a cross-sectional top view of a mixing drum according to an embodiment of the present invention;

fig. 8 is an assembled bottom exploded view of an inner aft frame and turbine blade frame provided by an embodiment of the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a separating and filtering device; 101. a middle cylinder; 102. a transition barrel; 103. a liquid inlet pipe; 104. a valve I; 105. a filter cartridge; 106. nanofiltration membrane; 107. a liquid outlet pipe; 108. a second valve; 109. a bottom collar; 110. a liquid separating pipe; 111. a third valve; 112. a pressurizing pipe; 113. a piston; 114. a spring; 115. a branch pipe; 2. a separation assisting component; 201. penetrating the rod; 202. a cylinder; 203. an inner frame; 204. a booster disc; 205. a through hole; 206. a baffle plate; 207. an inner ring plate; 208. a hanging rack; 209. a bevel carrier plate; 210. a stirring rod; 3. an anaerobic ammoxidation treatment device; 4. a delivery tube; 401. an outer collar; 402. a slant pipe; 5. a mixing drum; 501. a mixed liquid outlet pipe; 502. a power pump; 503. a valve IV; 504. an inner cylinder; 505. an outer guide frame; 506. an inner guide frame; 507. an inner net rack; 508. an end metal slider; 509. a magnet; 510. a climbing machine; 511. a limit stop; 512. a turbine blade holder; 513. a bottom disc; 514. a protrusion; 6. oxidation strengthening treatment device.

Description of the embodiments

The present invention will be specifically described with reference to examples below in order to make the objects and advantages of the present invention more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the invention and does not limit the scope of the invention strictly as claimed.

As shown in fig. 1-8, the aged garbage leachate treatment device comprises a separating and filtering device 1, a delivery pipe 4, a mixing drum 5 and an oxidation strengthening treatment device 6.

Examples

Referring to fig. 4, the sub-filtration device 1 comprises a central cartridge 101 and a plurality of sub-filtration cartridges 105 arranged on the outer wall of the central cartridge 101 in an annular array, wherein the sub-filtration cartridges 105 are communicated with the central cartridge 101 and are used for collecting filtrate containing high-concentration ammonia nitrogen components separated from landfill leachate, and a nanofiltration membrane 106 for separating ammonia nitrogen-containing filtrate is embedded between the central cartridge 101 and the sub-filtration cartridges 105.

Referring to fig. 1 to 3, all the filter cartridges 105 are commonly connected with a bottom ring pipe 109 through a bottom pipe, one end of the bottom ring pipe 109 is connected with a liquid separating pipe 110 connected with an inlet of the anaerobic ammonia oxidation treatment device 3, and a valve III 111 for controlling the internal circulation of the liquid separating pipe 110 is fixedly arranged in the middle of the liquid separating pipe 110; the bottom of put a section of thick bamboo 101 is connected with drain pipe 107 that is connected with mixing drum 5 top, and the one end fixed mounting of drain pipe 107 has valve two 108 that are used for controlling the inside circulation of drain pipe 107, the output of anaerobic ammonia oxidation treatment device 3 is connected with the delivery tube 4 that is used for leading into the inside of mixing drum 5 with the filtrate that is subjected to anaerobic ammonia oxidation treatment, and one side of the bottom of mixing drum 5 is connected with the mixed liquor exit tube 501 that is used for leading into the inside of oxidation strengthening treatment device 6 with the mixed liquor, and the power pump 502 that is used for taking out the mixed liquor and the valve four 503 that are used for controlling the inside circulation of mixed liquor exit tube 501 are installed to the both ends of mixed liquor exit tube 501, the inside integral type of mixing drum 5 is fixedly provided with interior barrel 504.

According to the structure, the old landfill leachate in the middle cylinder 101 is pretreated to separate filtrate containing high-concentration ammonia nitrogen components, the separated filtrate is temporarily stored in the filter cylinder 105, and organic matters which are difficult to biodegrade and other suspended and colloidal impurities are compressed in the concentrated solution; opening a valve III 111 to lead the filtrate in each sub-filter cylinder 105 into the anaerobic ammonia oxidation treatment device 3 for anaerobic ammonia oxidation treatment, removing high-concentration ammonia nitrogen in the filtrate, leading the filtrate after anaerobic ammonia oxidation denitrification treatment into the inner cylinder 504 through the leading-out pipe 4, leading the concentrated solution which is originally positioned in the middle cylinder 101 into the inner cylinder 504 through the liquid outlet pipe 107, and remixing the filtrate with the concentrated solution, wherein most ammonia nitrogen and total nitrogen in the mixed solution are removed by the anaerobic ammonia oxidation treatment device 3, so that only non-biodegradable COD and other substances are left; the power pump 502 and the valve IV 503 are opened, the mixed solution is led into the oxidation strengthening treatment device 6 for biochemical strengthening treatment, ammonia nitrogen and total nitrogen in COD and water are further removed, the treated percolate reaches the national specified emission standard, the above processes are solved, the influence of COD which is easy to be subjected to high concentration and difficult to be biodegraded on the denitrification process in the biological denitrification technology using anaerobic ammonia oxidation equipment is solved, the interference to the anaerobic ammonia oxidation rhodochrous is reduced, and the denitrification efficiency can be ensured when the anaerobic ammonia oxidation rhodochrous has the advantages of low carbon, energy saving and denitrification.

The working principle of the invention is as follows: preprocessing old landfill leachate in the middle cylinder 101 to separate filtrate containing high-concentration ammonia nitrogen components, temporarily storing the separated filtrate in the filter cylinder 105, and compressing organic matters which are difficult to biodegrade and other suspended and colloidal impurities in the concentrated solution; opening a valve III 111 to lead the filtrate in each sub-filter cylinder 105 into the anaerobic ammonia oxidation treatment device 3 for anaerobic ammonia oxidation treatment, removing high-concentration ammonia nitrogen in the filtrate, leading the filtrate after anaerobic ammonia oxidation denitrification treatment into the inner cylinder 504 through the leading-out pipe 4, leading the concentrated solution which is originally positioned in the middle cylinder 101 into the inner cylinder 504 through the liquid outlet pipe 107, and remixing the filtrate with the concentrated solution, wherein most ammonia nitrogen and total nitrogen in the mixed solution are removed by the anaerobic ammonia oxidation treatment device 3, so that only non-biodegradable COD and other substances are left; and (3) opening the power pump 502 and the valve IV 503, introducing the mixed solution into the oxidation strengthening treatment device 6 for biochemical strengthening treatment, and further removing ammonia nitrogen and total nitrogen in COD and water, so that the treated percolate reaches the national specified discharge standard.

Examples

Referring to fig. 4, a transition barrel 102 is integrally and fixedly arranged at the top of a middle barrel 101, a liquid inlet pipe 103 for introducing landfill leachate is fixedly connected to the top end of the transition barrel 102, and a valve I104 for controlling the circulation inside the liquid inlet pipe 103 is arranged at one end of the liquid inlet pipe 103; the top of each sub-filter cylinder 105 is fixedly connected with a booster pipe 112, the top of the inside of the booster pipe 112 is movably provided with a piston 113, a spring 114 is arranged inside the booster pipe 112 and below the piston 113, the top of the booster pipe 112 is fixedly connected with a branch pipe 115, and the tail end of each branch pipe 115 is connected with the liquid inlet pipe 103 in an inclined tee way; the height dimension of the middle cylinder 101 is larger than that of the sub-cylinder 105, and the volume of the internal space of the pressurizing pipe 112 is larger than that of the whole branch pipe 115.

According to the above structure, in the self-cleaning operation of the nanofiltration membrane 106, the valve III 111 is closed, when the liquid level of the filtrate in the filtration cartridge 105 to be separated reaches a certain height, the valve I104 is closed, at this time, the landfill leachate injected from the liquid inlet pipe 103 will enter each branch pipe 115, at this time, the gas in each branch pipe 115 will be compressed, then the piston 113 is moved and presses the spring 114 under the driving of the air pressure and the hydraulic pressure, the air in the original pressurization pipe 112 will be pressed into the filtration cartridge 105, because the valve III 111 is closed, the air pressure in the filtration cartridge 105 is raised, the filtrate in the filtration cartridge 105 will be caused to reversely pass through the nanofiltration membrane 106 and return to the middle-placed cartridge 101, in the process that the filtrate reversely passes through the nanofiltration membrane 106, the particles originally blocked in the gap of the nanofiltration membrane 106 will be washed out, thereby achieving the self-cleaning effect of the nanofiltration membrane 106, in this way, the cleaning operation of the nanofiltration membrane 106 is realized, the functions of the equipment are increased, and the equipment is ensured to be regularly used for a long time, the operation of cleaning the nanofiltration membrane 106 is ensured, in addition, when the valve III 111 is not needed, the additional electric power is not needed, the filtration membrane 106 is completely cleaned, and the equipment is completely is removed, and the filtration membrane 106 is completely cleaned by the filtration equipment by means of the filtration equipment, and the filtration equipment is simultaneously, and the filtration equipment is completely closed by closing by the valve III.

The working principle of the invention is as follows: in the self-cleaning operation of the nanofiltration membrane 106, the valve III 111 is closed, when the liquid level of the filtrate in the filtration cartridge 105 reaches a certain height, the valve I104 is closed, at this time, the landfill leachate injected from the liquid inlet pipe 103 enters into each branch pipe 115, at this time, the gas in each branch pipe 115 is compressed, then the piston 113 is moved and presses the spring 114 under the driving of the air pressure and the hydraulic pressure, the air in the original pressurizing pipe 112 is pressed into the filtration cartridge 105, and the air pressure in the filtration cartridge 105 is raised due to the closing of the valve III 111, so that the filtrate in the filtration cartridge 105 reversely passes through the nanofiltration membrane 106 and returns to the middle-arranged cartridge 101, and the particles originally blocked in the gaps of the nanofiltration membrane 106 are flushed out in the process that the filtrate reversely passes through the nanofiltration membrane 106, thereby achieving the self-cleaning effect of the nanofiltration membrane 106.

Examples

Referring to fig. 5-6, a separation assisting component 2 for accelerating separation of filtrate containing ammonia and nitrogen is assembled in the separation assisting component 2, the separation assisting component 2 comprises a penetrating rod 201 which is movably connected with a middle cylinder 101 in a plugging manner, an air cylinder 202 for controlling the penetrating rod 201 to move up and down is installed on the outer wall of the middle cylinder 101, an inner frame 203 is fixedly installed at the tail end of the penetrating rod 201 and located in the middle cylinder 101, an assisting disc 204 is rotatably assembled at the bottom of the inner frame 203, a plurality of through holes 205 are formed in an annular array manner on the edge of the assisting disc 204, hollow pipes are arranged on the lower surface of the assisting disc 204 and correspond to the positions of the through holes 205, a baffle plate 206 is fixedly arranged in each through hole 205, an inner ring plate 207 is movably installed in each hollow pipe, a hanging frame 208 for hanging the baffle plate 206 is arranged on the surface edge of each inner ring plate 207, an inclined support plate 209 is fixedly connected to the bottom of each hollow pipe, in the process of lifting the assisting disc 204, the through holes 205 are dredged, the garbage is percolated in the process of passing through the through holes 205, the inclined support plate 209 is pressed and the assisting disc 204 is driven to rotate, the lower surface of the assisting disc 204 is fixedly connected with the baffle plate 210 with the inclined support plate 207, and the stirring plate 210 is fixedly arranged on the inner ring plate 210, and the stirring plate is fixedly arranged on the stirring plate is in a small size of the stirring plate 209.

According to the above structure, after a certain volume of landfill leachate is injected into the middle cylinder 101, the injection process is stopped, and meanwhile, the cylinder 202 is started to drive the booster disc 204 to reciprocate, in the process that the booster disc 204 descends, the inner ring plate 207 is attached to the baffle plate 206, so that each through hole 205 is blocked, the booster disc 204 can give downward pressure to the landfill leachate, the filtration work is accelerated, in the process that the booster disc 204 ascends, the inner ring plate 207 is far away from the baffle plate 206, the through holes 205 are dredged, at this moment, in the process that the landfill leachate passes through the through holes 205, a certain pressure is given to the inclined bearing plate 209 and drives the booster disc 204 to rotate, the booster disc 204 is matched with the stirring rod 210, the stirring effect can be realized, thereby stirring the landfill leachate at other positions to the nanofiltration membrane 106, the separation booster assembly 2 is separated, in the process that the booster disc 204 reciprocates to reciprocate, the filtration speed of the landfill leachate at different positions can be accelerated, the landfill leachate can be driven to be continuously close to the nanofiltration membrane 106, the landfill leachate can be fully contacted with the nanofiltration membrane 106, and the filtration efficiency of the landfill leachate can be indirectly improved.

The working principle of the invention is as follows: after a certain volume of landfill leachate is injected into the middle cylinder 101, the injection process is stopped, and meanwhile, the cylinder 202 is started to drive the power-assisted disc 204 to reciprocate, in the descending process of the power-assisted disc 204, the inner ring plate 207 is attached to the baffle plate 206 to cause each through hole 205 to be blocked, so that the power-assisted disc 204 can give downward pressure to the landfill leachate, the filtering work is quickened, in the ascending process of the power-assisted disc 204, the inner ring plate 207 is far away from the baffle plate 206 to dredge the through holes 205, at the moment, in the process of the landfill leachate passing through the through holes 205, certain pressure is given to the inclined bearing plate 209 and the power-assisted disc 204 is driven to rotate, the power-assisted disc 204 is matched with the stirring rod 210 to achieve the stirring effect, and therefore the landfill leachate at other positions is stirred to the nanofiltration membrane 106.

Examples

Referring to fig. 3 and 7, the outer ring tube 401 is fixedly connected to the end of the delivery tube 4, and the outer ring tube 401 is fixedly installed outside the mixing drum 5, the inclined tube 402 is fixedly connected to the inner side of the outer ring tube 401 in an annular array, the inner cylinder 504 is integrally and fixedly arranged inside the mixing drum 5, and the end of the inclined tube 402 is obliquely inserted into the inner cylinder 504.

According to the above structure, since the end of the inclined inlet pipe 402 is inserted into the inner cylinder 504 in an inclined manner, a certain flow effect is generated between the filtrate and the concentrated solution in the mixing cylinder 5 after the filtrate enters the inner cylinder 504, and the internal mixed solution will generate a vortex-like flow process under the impact of tangential water flow, so as to improve the mixing effect of the filtrate and the concentrated solution.

Referring to fig. 7 to 8, a plurality of outer guide frames 505 are fixedly installed at the edge ring-shaped array of the mixing drum 5, a climbing machine 510 is slidably assembled at the inner side of each outer guide frame 505, magnets 509 are fixedly installed at the inner side of the climbing machine 510, inner guide frames 506 are fixedly arranged at positions, which are close to the outer guide frames 505, of the inner wall of the inner drum 504, an inner net frame 507 is assembled at the inner lifting position of the inner drum 504, end metal sliding blocks 508 are fixedly installed at the edge ring-shaped array of the inner net frame 507, and the end metal sliding blocks 508 are slidably installed inside the inner guide frames 506.

Referring to fig. 7-8, a turbine blade frame 512 is rotatably assembled on the upper surface of the inner net frame 507, blades with inclined angles are fixedly arranged on the inner side of the turbine blade frame 512 in an annular array manner, a bottom disc 513 is fixedly arranged on the lower surface of the center of the turbine blade frame 512, the bottom disc 513 is arranged below the center of the inner net frame 507, a limit stop 511 is fixedly arranged on the center of the inner net frame 507 in an annular array manner, and a protrusion 514 is fixedly arranged on the outer wall of the edge of the bottom disc 513 in an annular array manner.

According to the above structure, after the filtrate and the concentrated solution are mixed in the mixing drum 5, the carbon source is added simultaneously to achieve the denitrification effect, at this time, the mixed solution will generate a certain sludge in the reaction, in order not to affect the effect of the power pump 502 for pumping out the mixed solution, at this time, each climbing machine 510 is started to enable the magnet 509 to climb along the outer guide frame 505, under the effect of magnetic force, the inner guide frame 506 will also climb inside the inner cylinder 504 simultaneously, the end metal slide block 508 will slide upwards inside the corresponding inner guide frame 506, in the process that the inner net frame 507 and the inner net frame 512 move upwards together, the mixed solution will squeeze the paddle to a certain pressure, so that the turbine leaf frame 512 and the inner net frame 507 will simultaneously rotate relatively, and the bump 514 will be blocked by the limit stop 511, so that the turbine leaf frame 512 can only rotate a short distance in the process of climbing, at this time, the paddles in the turbine leaf frame 512 will block the gaps of the inner net frame 507, so that the inner net frame 507 can drive more sludge to move upwards during climbing, and the problem of sludge deposition is solved, and the work load of the power pump 502 is reduced due to sludge deposition.

The working principle of the invention is as follows: when filtrate and concentrated solution are mixed in the mixing drum 5, a carbon source is added simultaneously to achieve a denitrification effect, at the moment, the mixed solution can generate certain sludge in the reaction, in order not to influence the effect of pumping the mixed solution by the power pump 502, at the moment, each climbing machine 510 is started to enable the magnet 509 to climb along the outer guide frame 505, under the action of magnetic force, the inner guide frame 506 also climbs inside the inner cylinder body 504 simultaneously, the end metal sliding block 508 can slide upwards inside the corresponding inner guide frame 506, in the process that the inner net frame 507 and the inner net frame 512 move upwards together, the mixed solution can squeeze the paddles to have certain pressure, so that relative rotation can occur between the inner net frame 507 and the turbine frame 512 simultaneously, and the protrusions 514 can be blocked by the limit stop blocks 511, so that the turbine frame 512 can only rotate a small distance in the climbing process, and at the moment, the paddles in the turbine frame 512 can block gaps of the inner net frame 507, so that more sludge can be driven to move upwards during climbing, and the problem of sludge deposition is solved.

The aged garbage leachate treatment method uses the aged garbage leachate treatment device, and comprises the following specific steps:

s1: preprocessing old landfill leachate in the middle cylinder 101 to separate filtrate containing high-concentration ammonia nitrogen components, temporarily storing the separated filtrate in the filter cylinder 105, and compressing organic matters which are difficult to biodegrade and other suspended and colloidal impurities in the concentrated solution;

s2: after the garbage infiltration is injected into the middle cylinder 101, the injection process is stopped, and meanwhile, the cylinder 202 is started to drive the booster disc 204 to reciprocate, and in the process of descending the booster disc 204, each through hole 205 is blocked by the inner ring plate 207, so that the booster disc 204 can give downward pressure to the garbage infiltration liquid, the filtering work is quickened, in the process of ascending the booster disc 204, the through holes 205 are dredged, and in the process of penetrating the through holes 205, the garbage infiltration liquid can give pressure to the inclined bearing plate 209 and drive the booster disc 204 to rotate, and the stirring effect is realized by matching with the stirring rod 210, so that the garbage infiltration liquid at other positions is stirred to the nanofiltration membrane 106;

s3: adopting an anaerobic ammonia oxidation treatment device to remove total nitrogen in nanofiltration membrane filtrate, opening a valve III 111 to lead filtrate in each sub-filter cartridge 105 into the anaerobic ammonia oxidation treatment device 3 for anaerobic ammonia oxidation treatment;

s4: the filtrate after anaerobic ammonia oxidation denitrification treatment is led into the inner cylinder 504 through the lead-out pipe 4, and the concentrated solution which is originally positioned in the middle cylinder 101 is also led into the inner cylinder 504 through the liquid outlet pipe 107, at the moment, the filtrate and the concentrated solution are mixed again, and at the moment, the total nitrogen in the mixed solution is removed by the anaerobic ammonia oxidation treatment device 3;

s5: and opening the power pump 502 and the valve IV 503, and introducing the mixed solution into the oxidation strengthening treatment device 6 for biochemical strengthening treatment to further remove the total nitrogen in COD and water.

The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (6)

1. An aged landfill leachate treatment device which is characterized in that: the device comprises a sub-filtering device (1), a delivery pipe (4), a mixing drum (5) and an oxidation strengthening treatment device (6), wherein the sub-filtering device (1) comprises a central drum (101) and a plurality of sub-filtering drums (105) which are arranged on the outer wall of the central drum (101) in an annular array manner, the sub-filtering drums (105) are communicated with the central drum (101) and are used for collecting filtrate containing high-concentration ammonia nitrogen components separated from garbage percolate, and nanofiltration membranes (106) used for separating ammonia nitrogen filtrate are embedded between the central drum (101) and the sub-filtering drums (105);

all the filter cartridges (105) are connected with a bottom ring pipe (109) through a bottom pipeline, one end of the bottom ring pipe (109) is connected with a liquid separating pipe (110) connected with the inlet of the anaerobic ammonia oxidation treatment device (3), and a valve III (111) for controlling the internal circulation of the liquid separating pipe (110) is fixedly arranged in the middle of the liquid separating pipe (110); the bottom of the middle-arranged barrel (101) is connected with a liquid outlet pipe (107) connected with the top of the mixing barrel (5), one end of the liquid outlet pipe (107) is fixedly provided with a valve II (108) for controlling the internal circulation of the liquid outlet pipe (107), the output end of the anaerobic ammonia oxidation treatment device (3) is connected with a delivery pipe (4) for guiding filtrate subjected to anaerobic ammonia oxidation treatment into the mixing barrel (5), one side of the bottom of the mixing barrel (5) is connected with a mixed liquid outlet pipe (501) for guiding mixed liquid into the oxidation strengthening treatment device (6), two ends of the mixed liquid outlet pipe (501) are provided with a power pump (502) for extracting mixed liquid and a valve IV (503) for controlling the internal circulation of the mixed liquid outlet pipe (501), and an inner barrel (504) is fixedly arranged in an integral manner in the mixing barrel (5);

the outer wall of the mixing drum (5) is fixedly provided with a plurality of outer guide frames (505) in an annular array manner, a climbing machine (510) is assembled on the inner side of each outer guide frame (505) in a sliding manner, and a magnet (509) is fixedly arranged on the inner side of the climbing machine (510);

an inner guide frame (506) is fixedly arranged on the inner wall of the inner cylinder body (504) and close to the outer guide frame (505), an inner net frame (507) is assembled in the inner cylinder body (504) in a lifting mode, end metal sliding blocks (508) are fixedly arranged on the edge of the inner net frame (507) in an annular array mode, and the end metal sliding blocks (508) are slidably arranged in the inner guide frame (506);

the upper surface of the inner net rack (507) is rotatably assembled with a turbine blade rack (512), and blades with inclined angles are fixedly arranged on the inner side of the turbine blade rack (512) in an annular array manner;

the lower surface of the center of the turbine blade frame (512) is fixedly provided with a bottom disc (513), the bottom disc (513) is arranged below the center of the inner net frame (507), the center of the inner net frame (507) is fixedly provided with a limit stop (511) in an annular array manner, and the outer wall of the edge of the bottom disc (513) is fixedly provided with a protrusion (514) in an array manner;

a transition barrel (102) is integrally and fixedly arranged at the top of the middle barrel (101), a liquid inlet pipe (103) for guiding garbage percolate is fixedly connected to the top end of the transition barrel (102), and a valve I (104) for controlling the circulation inside the liquid inlet pipe (103) is arranged at one end of the liquid inlet pipe (103); the top of each sub-filter cylinder (105) is fixedly connected with a pressurizing pipe (112), a piston (113) is movably arranged at the top end of the inside of each pressurizing pipe (112), a spring (114) is arranged inside each pressurizing pipe (112) and below each piston (113), a branch pipe (115) is fixedly connected at the top end of each pressurizing pipe (112), and the tail end of each branch pipe (115) is connected with a liquid inlet pipe (103) in an inclined tee way;

the device is characterized in that a separation assisting component (2) for accelerating the separation of ammonia-nitrogen-containing filtrate is assembled in the separation assisting component (2), the separation assisting component (2) comprises a penetrating rod (201) which is movably connected with a middle cylinder (101), an air cylinder (202) for controlling the penetrating rod (201) to move up and down is mounted on the outer wall of the middle cylinder (101), an inner frame (203) is fixedly mounted at the tail end of the penetrating rod (201) and is positioned in the middle cylinder (101), an assisting disc (204) is rotatably assembled at the bottom of the inner frame (203), a plurality of through holes (205) are formed in an annular array at the edge of the assisting disc (204), hollow pipes are arranged at the positions of the lower surface of the assisting disc (204) corresponding to the through holes (205), baffle plates (206) are fixedly arranged in the inner parts of the through holes (205), inner ring plates (207) are movably mounted in the hollow pipes, hanging frames (208) for hanging the baffle plates (206) are fixedly connected with the bottoms of the inner ring plates (205), a plurality of the hollow plates (205) are fixedly connected with the bottoms of the hollow plates (205), the inclined plates (205) are rotatably driven by the inclined plates (209) in the process of dredging the inclined plates (209), and the garbage can be driven to pass through the through holes (209), and the edges of the lower surfaces of the power-assisted discs (204) are fixedly connected with stirring rods (210) for stirring.

2. The aged landfill leachate treatment device according to claim 1, wherein: the height dimension of the middle cylinder (101) is larger than that of the sub-filter cylinder (105), and the volume of the inner space of the pressurizing pipe (112) is larger than that of the whole branch pipe (115).

3. The aged landfill leachate treatment device according to claim 1, wherein: the inner diameter size of the inner ring plate (207) is smaller than the diameter size of the baffle plate (206), and the inclined bearing plates (209) and the stirring rod (210) are arranged at intervals.

4. The aged landfill leachate treatment device according to claim 1, wherein: the tail end of the delivery pipe (4) is fixedly connected with an outer ring pipe (401), the outer ring pipe (401) is fixedly arranged outside the mixing drum (5), and the inner side of the outer ring pipe (401) is fixedly connected with an inclined inlet pipe (402) in an annular array mode.

5. The aged refuse leachate treatment device according to claim 4, wherein: the end of the inclined tube (402) is inserted into the inner cylinder (504) in an inclined manner.

6. A method for treating aged landfill leachate, which uses the aged landfill leachate treatment device according to any one of claims 1 to 5, and is characterized by comprising the following specific steps:

s1: firstly, preprocessing old landfill leachate in a middle-placed barrel (101) to separate filtrate containing high-concentration ammonia nitrogen components, temporarily storing the separated filtrate in a filter barrel (105), and compressing organic matters which are difficult to biodegrade and other suspended and colloidal impurities in concentrated liquid;

s2: after the garbage infiltration is injected into the middle cylinder (101), the injection process is stopped, and meanwhile, the cylinder (202) is started to drive the booster disc (204) to reciprocate, and in the descending process of the booster disc (204), each through hole (205) is blocked by the inner ring plate (207), so that the booster disc (204) can give downward pressure to the garbage infiltration liquid, the filtering work is quickened, in the ascending process of the booster disc (204), the through holes (205) are dredged, and in the passing process of the through holes (205), the garbage infiltration liquid can give pressure to the inclined bearing plate (209) and drive the booster disc (204) to rotate, and the stirring rod (210) is matched to realize the stirring effect, so that the garbage infiltration liquid at other positions is stirred to the nanofiltration membrane (106);

s3: adopting an anaerobic ammonia oxidation treatment device to remove total nitrogen in nanofiltration membrane filtrate, opening a valve III (111) to lead filtrate in each sub-filter cartridge (105) into the anaerobic ammonia oxidation treatment device (3) for anaerobic ammonia oxidation treatment;

s4: introducing filtrate after anaerobic ammonia oxidation denitrification treatment into the inner cylinder body (504) through a delivery pipe (4), introducing concentrated solution which is originally positioned in the middle cylinder (101) into the inner cylinder body (504) through a delivery pipe (107), and remixing the filtrate and the concentrated solution at the moment, wherein total nitrogen in the mixed solution is removed by the anaerobic ammonia oxidation treatment device (3);

s5: and (3) opening a power pump (502) and a valve IV (503), and introducing the mixed solution into an oxidation strengthening treatment device (6) for biochemical strengthening treatment to further remove the total nitrogen in COD and water.