CN117466381B - Industrial wastewater recycling device with filtering structure - Google Patents
Industrial wastewater recycling device with filtering structure Download PDFInfo
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- CN117466381B CN117466381B CN202311814876.5A CN202311814876A CN117466381B CN 117466381 B CN117466381 B CN 117466381B CN 202311814876 A CN202311814876 A CN 202311814876A CN 117466381 B CN117466381 B CN 117466381B
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- fixedly connected
- rotating shaft
- rod
- rigid coupling
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- 239000010842 industrial wastewater Substances 0.000 title claims abstract description 15
- 238000001914 filtration Methods 0.000 title claims abstract description 13
- 238000004064 recycling Methods 0.000 title claims abstract description 10
- 238000006243 chemical reaction Methods 0.000 claims abstract description 74
- 230000008878 coupling Effects 0.000 claims abstract description 43
- 238000010168 coupling process Methods 0.000 claims abstract description 43
- 238000005859 coupling reaction Methods 0.000 claims abstract description 43
- 238000007789 sealing Methods 0.000 claims abstract description 12
- 239000007788 liquid Substances 0.000 claims description 61
- 238000003756 stirring Methods 0.000 claims description 49
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 48
- 238000007790 scraping Methods 0.000 claims description 14
- 230000005540 biological transmission Effects 0.000 claims description 10
- 239000010865 sewage Substances 0.000 claims description 7
- 230000001360 synchronised effect Effects 0.000 claims description 5
- 239000011550 stock solution Substances 0.000 claims description 3
- 230000000149 penetrating effect Effects 0.000 claims 2
- 239000002351 wastewater Substances 0.000 abstract description 37
- 238000000034 method Methods 0.000 abstract description 32
- 238000011282 treatment Methods 0.000 abstract description 9
- 238000011084 recovery Methods 0.000 abstract description 4
- 238000005086 pumping Methods 0.000 abstract description 3
- 239000003921 oil Substances 0.000 description 41
- AXCZMVOFGPJBDE-UHFFFAOYSA-L calcium dihydroxide Chemical compound [OH-].[OH-].[Ca+2] AXCZMVOFGPJBDE-UHFFFAOYSA-L 0.000 description 39
- UCKMPCXJQFINFW-UHFFFAOYSA-N Sulphide Chemical compound [S-2] UCKMPCXJQFINFW-UHFFFAOYSA-N 0.000 description 10
- 239000012535 impurity Substances 0.000 description 8
- 239000010720 hydraulic oil Substances 0.000 description 6
- 239000007787 solid Substances 0.000 description 6
- 239000000243 solution Substances 0.000 description 6
- 238000012545 processing Methods 0.000 description 5
- 239000012530 fluid Substances 0.000 description 4
- 230000036632 reaction speed Effects 0.000 description 4
- 230000000903 blocking effect Effects 0.000 description 3
- 239000003208 petroleum Substances 0.000 description 3
- 239000013049 sediment Substances 0.000 description 3
- 239000000126 substance Substances 0.000 description 3
- 239000010779 crude oil Substances 0.000 description 2
- 238000007599 discharging Methods 0.000 description 2
- 238000000926 separation method Methods 0.000 description 2
- 230000002411 adverse Effects 0.000 description 1
- 230000007423 decrease Effects 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 239000003344 environmental pollutant Substances 0.000 description 1
- 230000013011 mating Effects 0.000 description 1
- 238000002156 mixing Methods 0.000 description 1
- 239000000203 mixture Substances 0.000 description 1
- 239000003129 oil well Substances 0.000 description 1
- 239000003209 petroleum derivative Substances 0.000 description 1
- 231100000719 pollutant Toxicity 0.000 description 1
- 238000012958 reprocessing Methods 0.000 description 1
- 230000000630 rising effect Effects 0.000 description 1
- 238000004062 sedimentation Methods 0.000 description 1
- 150000004763 sulfides Chemical class 0.000 description 1
- -1 suspended matters Substances 0.000 description 1
Classifications
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/40—Devices for separating or removing fatty or oily substances or similar floating material
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F11/00—Treatment of sludge; Devices therefor
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2101/00—Nature of the contaminant
- C02F2101/10—Inorganic compounds
- C02F2101/101—Sulfur compounds
Landscapes
- Chemical & Material Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Hydrology & Water Resources (AREA)
- Engineering & Computer Science (AREA)
- Environmental & Geological Engineering (AREA)
- Water Supply & Treatment (AREA)
- Organic Chemistry (AREA)
- Analytical Chemistry (AREA)
- Removal Of Floating Material (AREA)
- Separation Of Suspended Particles By Flocculating Agents (AREA)
Abstract
The invention provides an industrial wastewater recycling device with a filtering structure, and relates to the technical field of industrial wastewater recycling devices. The method aims at solving the technical problem that waste water is easily synchronously pumped out in the oil pumping process, so that the waste water is mixed in an oil layer, and the subsequent treatment of the oil layer is influenced. The utility model provides an industrial waste water recycling device who contains filtration, includes the support frame, the support frame rigid coupling has the retort, the retort detachable is connected with end cover and bottom, retort sealing sliding connection has the cone lid, cone lid runs through the rigid coupling has the raceway that runs through the end cover, cone lid runs through the rigid coupling has the blow off pipe. According to the invention, the cone-shaped cover moves downwards, so that the height of the oil layer is continuously increased, the oil layer flows into the drain pipe, the drain pipe discharges the oil layer outwards, and the influence on the subsequent recovery treatment of wastewater in the reaction tank is prevented.
Description
Technical Field
The invention relates to the technical field of industrial wastewater recovery devices, in particular to an industrial wastewater recovery device with a filtering structure.
Background
The petroleum processing refers to the process of obtaining various petroleum products after processing crude oil, in the process of processing crude oil, a large amount of water is needed for physical and chemical separation, impurity removal and other treatments, the water can take away various pollutants and impurities in petroleum to form wastewater containing oil, suspended matters, chemical and other substances, suspended matters in the wastewater can be gradually deposited and combined with water along with the flowing of fluid and some operations in the treatment process to form oily sediment, the wastewater is mostly introduced into a sedimentation tank at present, after oil and water in the wastewater are layered, an oil layer is pumped out through a pipeline, but the contact surface between the water layer and the oil layer is wider, the wastewater is easily pumped out synchronously in the oil pumping process, so that the wastewater is mixed in the oil layer, and the subsequent treatment of the oil layer is influenced.
Disclosure of Invention
The invention provides an industrial wastewater recycling device with a filtering structure, which aims to overcome the defect that wastewater is easily synchronously pumped out in the oil pumping process and is mixed in an oil layer to influence the subsequent treatment of the oil layer.
The technical proposal is as follows: the utility model provides an industrial waste water recycling device who contains filtration, includes the support frame, the support frame rigid coupling has the retort, the retort detachable is connected with end cover and bottom, retort sealing sliding connection has the toper lid, the end cover is close to one side rigid coupling of bottom has the first electric putter of mirror image distribution, the flexible end of first electric putter with the toper lid is kept away from one side rigid coupling of bottom, the toper lid runs through the rigid coupling has the raceway that runs through the end cover, the raceway of toper lid with end cover sliding connection, just be provided with the check valve in the raceway of toper lid, the toper lid runs through the rigid coupling has the blow off pipe, the blow off pipe runs through the end cover and rather than sliding connection, blow off pipe and oil-well pump intercommunication, the bottom rigid coupling has the drain pipe that sets up the filter screen.
More preferably, the drain pipe rigid coupling and intercommunication have the connecting pipe, the connecting pipe is provided with the spout, connecting pipe sealing sliding connection has first movable plate, first movable plate rigid coupling has first arc baffle, first arc baffle with spout sliding connection on the connecting pipe, first movable plate is provided with the through-hole, first movable plate sealing sliding connection has first interception board, first interception board with the through-hole cooperation on the first movable plate, first interception board runs through first arc baffle and rather than sliding connection, the connecting pipe rigid coupling has the link, the link rigid coupling has the hydraulic telescoping rod, the flexible end of hydraulic telescoping rod with first arc baffle rigid coupling, the link is kept away from one side rigid coupling of drain pipe has the elastic telescoping plate, the flexible end rigid coupling of elastic telescoping plate has the pipe, the inside sealing sliding connection of stock solution pipe has first pushing disc, first pushing disc passes through the spliced pole stock solution board rigid coupling, the link of hydraulic telescoping rod with the fixed part of hydraulic telescoping rod communicates.
More preferably, the first moving plate and the first intercepting plate each have a density greater than that of oil and less than that of water.
More preferably, the support frame has the second electric putter of mirror image distribution through the connecting piece rigid coupling, the mirror image distribution the flexible end of second electric putter all runs through the bottom and with bottom sliding connection, the mirror image distribution the flexible end of second electric putter has the second movable plate of rigid coupling jointly, the retort rigid coupling has the movable shell to communicate, the inside sliding connection who removes the shell has the fixed plate, the fixed plate with the second movable plate rotates to be connected, the fixed plate with the second movable plate all is provided with the arc through-hole that communicates and circumference evenly distributed each other, the second movable plate is provided with circumference evenly distributed's recess, sliding connection has the second interception board in the recess of second movable plate, the second interception board with the rigid coupling has the spring between the second movable plate, the second interception board with adjacent through-hole cooperation on the fixed plate, one of them the second interception board rigid coupling has the run through the bottom and rather than sliding connection's outlet pipe, the retort has the first motor through the connecting piece rigid coupling, first motor output shaft passes through between the first movable housing and the transmission assembly.
More preferably, the second blocking plate is provided with an inclined surface, and the through hole of the fixing plate is provided with an inclined surface matched with the inclined surface on the adjacent second blocking plate.
More preferably, the support frame is fixedly connected with a second motor through a connecting piece, the end cover is rotationally connected with a rotating shaft, the rotating shaft is positioned in the reaction tank, the rotating shaft penetrates through the bottom cover, the second movable plate and the fixed plate, an output shaft of the second motor is in transmission with the rotating shaft through a synchronous belt, the rotating shaft is slidably connected with a scraping plate, the scraping plate is matched with the fixed plate, the reaction tank is fixedly connected with a third electric push rod in mirror image distribution through a connecting component, and the telescopic ends of the third electric push rod are fixedly connected with the bottom cover through connecting pieces.
More preferably, the hydraulic device further comprises a connecting block which is uniformly distributed in the circumferential direction, wherein the connecting block is uniformly and slidingly connected with the rotating shaft in the circumferential direction, the connecting block is uniformly and fixedly connected with a stirring rod, the stirring rod penetrates through the adjacent connecting block, the stirring rod is uniformly distributed in the circumferential direction, the rotating shaft is provided with blind holes which are mutually communicated, the stirring rod is provided with through holes which are uniformly distributed in the axial direction, a one-way valve is arranged in the through holes of the stirring rod, the bottom cover is hermetically and slidingly connected with a connecting seat, the connecting seat is hermetically and slidingly connected with the rotating shaft, the connecting seat is fixedly connected with a second moving plate, the connecting seat is inlaid with a hydraulic push rod which is uniformly distributed in the circumferential direction, the telescopic ends of the hydraulic push rod are respectively fixedly connected with the adjacent connecting block, the connecting seat is rotationally connected with a liquid storage ring, the liquid storage ring is externally connected with a connecting ring which is fixedly connected with the connecting seat, the connecting ring is provided with a through hole which is uniformly distributed in the circumferential direction, the connecting ring is fixedly connected with the connecting seat, and the connecting seat is fixedly connected with the connecting seat.
More preferably, the size of the through holes uniformly distributed in the axial direction on the stirring rod increases with the distance from the rotating shaft.
More preferably, the support frame has the liquid reserve tank through the connecting piece rigid coupling, the liquid reserve tank with the rotation axis rotates to be connected, the liquid reserve tank with blind hole intercommunication on the rotation axis, the liquid reserve tank is close to one side rigid coupling of bottom has the fourth electric putter of mirror image distribution, the inside sliding connection of liquid reserve tank has the second to push away the dish, mirror image distribution the flexible end of fourth electric putter all with the second pushes away a set rigid coupling, be provided with the through-hole on the second pushes away the dish, be provided with the check valve in the through-hole of second pushing away the dish, the inside sliding connection of liquid reserve tank has the limiting plate, sliding connection has the third movable plate in the blind hole of rotation axis, the third movable plate rigid coupling have with the connecting rod of limiting plate rigid coupling, the rotation axis keep away from one side of liquid reserve tank with the third movable plate is kept away from be provided with the cavity of filling the thermal inductance gas between one side of liquid reserve tank, the liquid reserve tank external has the input pump, the connecting rod is provided with the through-hole, just the connecting rod is close to the one end of limiting plate is provided with the hole, the second pushes away from the connecting rod has the arc-shaped connecting rod to be provided with the connecting rod.
More preferably, the spacing sliding connection of rotation axis has circumference evenly distributed's second arc baffle, circumference evenly distributed the second arc baffle respectively with adjacent through-hole cooperation on the rotation axis, circumference evenly distributed the second arc baffle all with the rigid coupling has first elastic component between the rotation axis, circumference evenly distributed all sliding connection has the movable tube in the blind hole of stirring rod, the movable tube with adjacent through-hole cooperation on the rotation axis, just the movable tube with the through-hole on the rotation axis all is provided with the slope anchor ring of mutually supporting, the movable tube with adjacent the rigid coupling has circumference evenly distributed's second elastic component between the stirring rod.
The invention has the following advantages: according to the invention, the cone-shaped cover moves downwards, so that the height of the oil layer is continuously increased, the oil layer flows into the drain pipe, the drain pipe discharges the oil layer outwards, and the influence on the subsequent recovery treatment of wastewater in the reaction tank is prevented.
The communicating state of the sewage drain pipe is changed through the different positions of the first movable plate in water and oil, so that waste water in the reaction tank is prevented from being discharged outwards through the sewage drain pipe and is mixed with an oil layer again, and the subsequent treatment of the oil layer is influenced.
Through mutually supporting of fixed plate and second movable plate, cut apart the water layer and the mud layer in the retort, prevent to cause the influence to the in-process of water layer processing at the follow-up.
The mud layer is stirred by the stirring rod, so that the mud layer is mixed with the water layer again, and the oil remained in the mud layer is contacted with the water layer again and is upwardly blended into the oil layer at the upper side, so that the oil content in the mud layer is reduced.
And the calcium hydroxide solution is added into the reaction tank in batches through the second pushing disc, so that the calcium hydroxide solution is prevented from being gradually consumed along with the calcium hydroxide solution after being added into the waste water of the reaction tank at one time, sulfide in the waste water of the reaction tank is also gradually consumed, the reaction speed of sulfide and the calcium hydroxide solution in the subsequent reaction tank is reduced, and the time consumed in the reaction process is increased.
Drawings
FIG. 1 is a schematic perspective view of the present invention;
FIG. 2 is a schematic cross-sectional perspective view of a reaction tank and a movable housing of the present invention;
FIG. 3 is a schematic perspective view of the cone cover, the first electric push rod and the drain pipe of the present invention;
FIG. 4 is a schematic cross-sectional perspective view of a drain pipe and a connecting pipe according to the present invention;
FIG. 5 is a schematic perspective view of a movable housing and a stationary plate according to the present invention;
Fig. 6 is a schematic perspective view of a second moving plate and a fixed plate according to the present invention;
FIG. 7 is a schematic perspective view of a stirring rod and a connecting seat according to the present invention;
FIG. 8 is a schematic perspective view of a second pusher plate and a limiting plate according to the present invention;
FIG. 9 is a schematic perspective view of a liquid storage ring and a connecting ring according to the present invention;
FIG. 10 is a schematic perspective view of a second arcuate baffle and a first resilient member of the present invention;
FIG. 11 is an exploded view of the shaft and stirring rod mating relationship of the present invention.
Wherein: 1-support frame, 2-reaction tank, 3-end cover, 4-bottom cover, 5-conical cover, 6-first electric putter, 7-drain, 201-connecting pipe, 202-first moving plate, 203-first arc baffle, 204-first interception plate, 205-connecting frame, 206-hydraulic telescopic rod, 207-elastic telescopic plate, 208-liquid storage pipe, 209-first push plate, 301-second electric putter, 302-second moving plate, 303-moving shell, 304-fixed plate, 3041-second interception plate, 305-first motor, 306-second motor, 307-rotating shaft, 308-scraper, 401-third electric putter, 501-connecting block, 502-stirring rod, 503-connecting seat, 504-hydraulic putter, 505-liquid storage ring, 506-connecting ring, 601-liquid storage tank, 602-fourth electric putter, 603-second push plate, 604-limit plate, 605-third moving plate, 606-connecting rod, 701-second arc baffle, 702-first elastic piece, 703-second elastic piece, 704-second elastic piece.
Detailed Description
Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functionality throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.
Example 1: the utility model provides an industrial waste water recycling device who contains filtration, as shown in fig. 1-3, including support frame 1, support frame 1 rigid coupling has retort 2, retort 2's upside detachable is connected with end cover 3, retort 2's downside detachable is connected with bottom 4, end cover 3 and bottom 4 all with retort 2 sealing fit, retort 2's inside sealing sliding connection has conical cover 5, conical cover 5 downside's diameter is greater than the diameter of upside, be used for leading the fluid in retort 2, make retort 2 interior fluid's high rising, end cover 3's downside rigid coupling has two first electric putter 6 that are the front and back mirror image distribution, two first electric putter 6's telescopic end all with conical cover 5's upside rigid coupling, by two first electric putter 6 jointly drive conical cover 5 downwardly moving, conical cover 5 runs through the rigid coupling and has the raceway that runs through end cover 3, conical cover 5's raceway and end cover 3 sliding connection, and be provided with the check valve in conical cover 5 (for showing in the current device figure) in the diameter of the interior fluid of conical cover 5, be arranged in the drain pump 7 that need be arranged in the drain pipe 7 of draining pump 7 in the side of the interior of retort 2, and the drain pipe 7 is connected with drain pipe 7 to drain pipe 7 in the drain pipe, simultaneously, drain pipe 7 is connected to drain pipe 7.
As shown in fig. 3 and 4, the middle part of the drain pipe 7 is fixedly connected and communicated with a connecting pipe 201, the right side of the connecting pipe 201 is provided with a chute, the inside of the connecting pipe 201 is in sealed sliding connection with a first movable plate 202, the right side of the first movable plate 202 is fixedly connected with a first arc baffle 203, the first arc baffle 203 is driven by the first movable plate 202 to synchronously move up and down, the first arc baffle 203 is in sliding connection with the chute on the connecting pipe 201 and is used for shielding the chute on the connecting pipe 201 to prevent oil from leaking outwards, the first movable plate 202 is provided with a through hole, the first movable plate 202 is in sealed sliding connection with a first interception plate 204, the first interception plate 204 is matched with the through hole on the first movable plate 202 and is used for plugging the through hole on the first movable plate 202, the density of the first movable plate 202 and the first interception plate 204 is larger than that of oil and smaller than water along the drain pipe 7, the positions of the first movable plate 202 and the first interception plate 204 are changed according to the density of liquid flowing in the sewage drain pipe 7, the first interception plate 204 is in sliding connection with the first arc baffle 203, the first interception plate 204 penetrates through the first arc baffle 203, a connecting frame 205 is fixedly connected to the upper side of the connecting pipe 201, a hydraulic telescopic rod 206 is fixedly connected to the connecting frame 205, the telescopic end of the hydraulic telescopic rod 206 is fixedly connected with the first arc baffle 203, the telescopic end of the hydraulic telescopic rod 206 is driven by the first arc baffle 203 to synchronously move up and down, an elastic telescopic plate 207 is fixedly connected to the right side of the connecting frame 205, a liquid storage pipe 208 is fixedly connected to the telescopic end of the elastic telescopic plate 207, a first push plate 209 is in sealing sliding connection with the inner part of the liquid storage pipe 208, the first push plate 209 is fixedly connected with the first interception plate 204 through a connecting column, the first push plate 209 drives the first interception plate 204 to move leftwards to shield a through hole on the first movable plate 202, the fixed part of the hydraulic telescopic rod 206 is communicated with the liquid storage pipe 208, the telescopic end of the hydraulic telescopic rod 206 is driven by the first arc baffle 203 to move upwards and input hydraulic oil in the fixed part of the hydraulic telescopic rod 206 into the liquid storage pipe 208, the first push plate 209 is driven to move leftwards, and then the first push plate 209 shields the through hole on the first movable plate 202 in the process that the first movable plate 202 moves upwards under the action of wastewater, so that wastewater in the reaction tank 2 is prevented from flowing outwards along the sewage discharge pipe 7.
As shown in fig. 5 and 6, the supporting frame 1 is fixedly connected with two second electric push rods 301 which are in front-back mirror image distribution through a connecting piece, the telescopic ends of the two second electric push rods 301 penetrate through the bottom cover 4 and are in sliding connection with the bottom cover 4, the telescopic ends of the two second electric push rods 301 are fixedly connected with a second moving plate 302 together, the two second electric push rods 301 drive the second moving plate 302 to move up and down together, the lower part of the reaction tank 2 is fixedly connected and communicated with a moving shell 303, the inside of the moving shell 303 is in sliding connection with a fixed plate 304, the fixed plate 304 is rotationally connected with the second moving plate 302, the fixed plate 304 synchronously moves up and down along with the second moving plate 302, four arc-shaped through holes which are uniformly distributed in the circumferential direction are arranged on the fixed plate 304, the four arc-shaped through holes on the fixed plate 304 are respectively communicated with the adjacent arc-shaped through holes on the second moving plate 302, the device is used for guiding a mud layer of the wastewater in the reaction tank 2 after standing and layering, so that the wastewater slides down to the upper side of the bottom cover 4, four grooves which are uniformly distributed in the circumferential direction are arranged on the upper side of the second movable plate 302, the four grooves on the second movable plate 302 are distributed with four through holes on the second movable plate 302 in a staggered manner, the second interception plates 3041 are slidably connected in the four grooves of the second movable plate 302, the grooves on the second movable plate 302 are blocked by the fixed plate 304 in the initial position, the four second interception plates 3041 are respectively positioned in the adjacent grooves on the second movable plate 302, springs are fixedly connected between the four second interception plates 3041 and the second movable plate 302, the springs between the four second interception plates 3041 and the second movable plate 302 are in a compressed state in the initial state, the four second interception plates 3041 are respectively matched with the adjacent through holes on the fixed plate 304 for blocking the through holes on the fixed plate 304, the second interception plate 3041 on the left side is fixedly connected with and communicated with a water outlet pipe, the water outlet pipe on the second interception plate 3041 on the left side penetrates through the bottom cover 4 and is in sliding connection with the bottom cover, the water outlet pipe on the second interception plate 3041 in the initial state is blocked by the fixed plate 304, the reaction tank 2 is fixedly connected with the first motor 305 through a connecting piece, an output shaft of the first motor 305 and the movable shell 303 are driven by the output shaft of the first motor 305 to rotate through gear group transmission, the fixed plate 304 is driven to rotate, four through holes on the fixed plate 304 are respectively staggered with adjacent through holes on the second movable plate 302, the four second interception plates 3041 are respectively moved upwards under the action of adjacent springs to block the adjacent through holes on the fixed plate 304, so that a water layer and a mud layer in the reaction tank 2 are divided, the through holes on the fixed plate 304 are provided with inclined planes, and in the reset process of the fixed plate 304, the inclined planes on the fixed plate 304 are used for downwards extruding the second interception plate 3041 and downwards moving.
As shown in fig. 5 and 6, the support frame 1 is fixedly connected with a second motor 306 through a connecting piece, the end cover 3 is rotatably connected with a rotating shaft 307, the rotating shaft 307 is located inside the reaction tank 2, the rotating shaft 307 penetrates through the bottom cover 4, the second moving plate 302 and the fixed plate 304, an output shaft of the second motor 306 and the rotating shaft 307 are driven by an output shaft of the second motor 306 to rotate through synchronous belt transmission, the rotating shaft 307 is slidably connected with a scraping plate 308, the scraping plate 308 is driven by the rotating shaft 307 to synchronously rotate, the scraping plate 308 is matched with the fixed plate 304, in the process of upward movement of the fixed plate 304, residual mud on the upper side surface of the fixed plate 304 is scraped by the scraping plate 308, mud is prevented from entering a water layer in the process of dividing a water layer and a mud layer in the reaction tank 2, the two third electric push rods 401 distributed in a front-back mirror mode are fixedly connected with the reaction tank 2 through connecting components, telescopic ends of the two third electric push rods 401 are fixedly connected with the bottom cover 4 through connecting pieces, and the two third electric push rods 401 are jointly driven to move up and down, the bottom cover 4 and are separated from the reaction tank 2 through the scraping plate 308, and the bottom cover 4 is conveniently cleaned up and accumulated mud on the bottom cover 4 by workers.
When the device is used for treating oily wastewater, a worker discharges the wastewater into the reaction tank 2 from the water delivery pipe on the end cover 3 until the height of the upper liquid level of the wastewater stored in the reaction tank 2 is flush with the height of the lower side of the conical cover 5, the worker stops discharging the wastewater into the reaction tank 2, and keeps the wastewater stored in the reaction tank 2 for a certain time until the liquid in the reaction tank 2 is divided into an oil layer-a water layer-a mud layer, then the worker starts two first electric push rods 6, the telescopic ends of the first electric push rods 6 synchronously drive the conical cover 5 to move downwards, the conical cover 5 gradually moves downwards along with the gradual downward movement of the conical cover 5, the contact area between the upper surface of the oil layer and the conical cover 5 gradually decreases, and the height of the oil layer continuously increases.
In the process of downward movement of the conical cover 5, until the upper surface of the oil layer contacts with the lower port of the drain pipe 7, the conical cover 5 continues to move downward at this time to enable the oil layer to flow into the drain pipe 7, and the oil flowing into the drain pipe 7 flows upward through the through hole on the first movable plate 202, the oil layer is discharged outwards, adverse influence is prevented from being generated in the subsequent process of recycling wastewater in the reaction tank 2, until the oil layer in the reaction tank 2 is discharged, at this time, the conical cover 5 continues to move downward to enable the water layer to start to flow into the drain pipe 7, until the water layer contacts with the first movable plate 202, the first movable plate 202 is subjected to buoyancy force of water to move upwards along the connecting pipe 201 and drives the first arc baffle 203 and the first interception plate 204 to move upwards synchronously, the first interception plate 204 drives the first push plate 209 to move upwards synchronously, the first telescopic end of the elastic telescopic plate 207 is simultaneously pushed upwards, the elastic telescopic plate 207 compresses the storage force, the hydraulic rod 206 is driven by the first arc baffle 203 to drive the telescopic end of the telescopic rod 206 to move upwards, the hydraulic oil pump 7 is stopped by the first push rod 206, the first interception plate 204 is driven by the first arc baffle plate 202 to move upwards, the first interception plate 204 is stopped by the first interception plate 204 is moved upwards, the first end of the hydraulic rod is stopped by the first interception plate is gradually, the first interception plate is stopped by the first interception plate is moved upwards, and the water is stopped by the first interception plate is moved upwards, and the first worker is stopped by the end is moved upwards, and the first interception plate is moved upwards, and the end is moved upwards by the first interception plate 7, and moves upwards is moved by the first interception plate, the influence on the water layer in the subsequent reprocessing process is prevented until the water-oil mixture in the blow-off pipe 7 is extracted, the worker stops the oil pump and reversely starts the two first electric push rods 6 at the same time, and the two first electric push rods 6 drive the conical cover 5 to reset to the initial position.
In the process of upward resetting of the conical cover 5, the conical cover 5 moves upward to lose contact with a water layer, meanwhile, residual water on the lower side of the sewage pipe 7 slides downward, the first movable plate 202 is not subjected to buoyancy of water, meanwhile, the telescopic end of the elastic telescopic plate 207 is loosened, the telescopic end of the elastic telescopic plate 207 drives parts such as the liquid storage pipe 208 to synchronously reset to an initial position, the liquid storage pipe 208 drives the first interception plate 204 to synchronously move downward through the transmission of the first push plate 209 in the process of downward movement, the first interception plate 204 drives the first arc baffle 203 to move downward, the first arc baffle 203 drives the telescopic end of the hydraulic telescopic rod 206 to move downward, meanwhile, hydraulic oil in the liquid storage pipe 208 is pumped back to the fixed part of the hydraulic telescopic rod 206 again, the first push plate 209 is driven to reset rightward, and the first interception plate 204 is synchronously driven by the first push plate 209 to move rightward, so that the through holes on the first movable plate 202 are opened again for the next use.
After the oil layer in the reaction tank 2 is pulled out, the worker starts the two second electric push rods 301, the telescopic ends of the two second electric push rods 301 synchronously drive the second moving plate 302 and other parts connected with the second moving plate 302 to move upwards until the lower side surface of the second moving plate 302 is positioned on the upper side surface of the mud layer, the worker stops the two second electric push rods 301, meanwhile, the worker starts the second motor 306, the output shaft of the second motor 306 drives the rotating shaft 307 to synchronously rotate through the transmission of the synchronous belt, the rotating shaft 307 drives the scraping plate 308 to rotate, and the scraping plate 308 scrapes the mud remained on the upper side surface of the fixed plate 304, so that the mud remained on the fixed plate 304 slides downwards along the four through holes on the fixed plate 304.
After the residual mud on the upper side of the fixed plate 304 is cleaned, a worker closes the second motor 306 and simultaneously starts the first motor 305, an output shaft of the first motor 305 drives the movable shell 303 to synchronously rotate through the transmission of the gear set, the movable shell 303 drives the fixed plate 304 to synchronously rotate, the fixed plate 304 and the through holes on the second movable plate 302 are staggered until the fixed plate 304 rotates by 45 degrees, at this time, the worker closes the first motor 305, at this time, the four second interception plates 3041 on the second movable plate 302 are respectively moved to the positions matched with the four through holes on the fixed plate 304, the four second interception plates 3041 are respectively moved upwards under the action of adjacent springs until the four second interception plates 3041 are respectively inserted into the adjacent through holes on the fixed plate 304 and the upper side faces of the four second interception plates 3041 are all flush with the upper side faces of the fixed plate 304, at this time, the fixed plate 304 and the second movable plate 302 are mutually matched, the water layer and the mud layer in the reaction tank 2 are separated, and the influence on the water layer in the subsequent treatment process is prevented.
After the water layer and the mud layer in the reaction tank 2 are separated, the mud layer in the reaction tank 2 falls on the bottom cover 4 at the moment, then a worker opens a drain pipe on the bottom cover 4 to drain residual water in the mud layer until the drain pipe on the bottom cover 4 is not continuously outward discharged, the worker starts the two third electric push rods 401, telescopic ends of the two third electric push rods 401 are matched with each other to jointly drive the bottom cover 4 to move downwards, the bottom cover 4 is disconnected with the reaction tank 2, mud accumulated on the upper side of the bottom cover 4 is cleaned by the worker, after the worker cleans the mud on the bottom cover 4, the worker reversely starts the two third electric push rods 401, the two third electric push rods 401 drive the bottom cover 4 to reset upwards until the bottom cover 4 moves upwards to be matched with the reaction tank 2 again, and the worker stops the two third electric push rods 401.
In the process of discharging the water remained in the mud layer, a small amount of sediment accumulated on the bottom cover 4 flows out along with the water, and the discharged water and the sediment contained therein are mixed by the staff to the wastewater to be treated next time for backflow.
After the solution in the reaction tank 2 is discharged, a worker reversely starts the first motor 305, the output shaft of the first motor 305 drives the movable housing 303 and other parts connected with the movable housing 303 to synchronously reset to the initial position, in the process, the fixed plate 304 synchronously rotates along with the movable housing 303, in the process of rotating the fixed plate 304, the four second interception plates 3041 are respectively extruded by inclined surfaces of adjacent through holes on the fixed plate 304 to synchronously move downwards, the four second interception plates 3041 synchronously compress adjacent springs, the four second interception plates 3041 are enabled to move downwards again into the four grooves of the second movable plate 302, the water outlet pipe on the second interception plates 3041 is enabled to be blocked by the fixed plate 304, and the four through holes on the fixed plate 304 are respectively communicated with the adjacent through holes on the second movable plate 302 until the device is reset to the initial position, and then the worker turns off the first motor 305.
In the process that the fixed plate 304 synchronously rotates along with the movable shell 303, the solid impurities left on the upper side surface of the fixed plate 304 slide down to the bottom cover 4 along the through holes of the fixed plate 304 until the movable shell 303 is reset to the initial position, a worker starts the second motor 306 again, the output shaft of the second motor 306 drives the scraping plate 308 to rotate through the transmission of the rotating shaft 307, the scraping plate 308 cleans the solid impurities left on the upper side surface of the fixed plate 304, in the process, the solid impurities left on the fixed plate 304 slide down along the through holes of the fixed plate 304 and the second movable plate 302 until the solid impurities on the fixed plate 304 are cleaned, the worker reversely starts the two second electric push rods 301 and simultaneously restarts the two third electric push rods 401, the second movable plate 302 and the fixed plate 304 are reset to the initial position, the reaction tank 2 and the bottom cover 4 are disconnected again, the worker cleans the solid impurities on the bottom cover 4, after the solid impurities on the bottom cover 4 are cleaned, the worker reversely starts the two third electric push rods 401 to reset the bottom cover 4 until the bottom cover 4, the second movable plate 302 and the fixed plate 302 are reset to the initial position, and the two electric push rods 301 are stopped for the second time.
Example 2: on the basis of the embodiment 1, as shown in fig. 7-10, the device further comprises six connecting blocks 501 which are uniformly distributed in the circumferential direction, wherein the six connecting blocks 501 are all connected with the rotating shaft 307 in a sliding manner, stirring rods 502 are fixedly connected with the six connecting blocks 501, the rotating shaft 307 synchronously drives the six stirring rods 502 to rotate so as to stir a mud layer in the reaction tank 2, the mud layer is mixed with a water layer again, oil remained in the mud layer is contacted with the water layer again, the six stirring rods 502 respectively penetrate through the adjacent connecting blocks 501, blind holes which are mutually communicated are formed in the six stirring rods 502 and the rotating shaft 307, through holes which are uniformly distributed in the axial direction are formed in the six stirring rods 502 and are used for adding calcium hydroxide solution into the reaction tank 2 so as to remove sulfides in waste water in the reaction tank 2, the size of the through holes which are uniformly distributed in the axial direction on the stirring rods 502 is increased along with the increase of the distance between the stirring rods and the rotating shaft 307, the stirring rod 502 is enabled to discharge calcium hydroxide solution into the reaction tank 2 more uniformly, a one-way valve (which is not shown in the prior device drawing) is arranged in a through hole of the stirring rod 502, waste water in the reaction tank 2 is prevented from flowing into the through hole of the stirring rod 502, a connecting seat 503 is connected with a bottom cover 4 in a sealing sliding manner, the connecting seat 503 is connected with a rotating shaft 307 in a sealing sliding manner, the connecting seat 503 is fixedly connected with a second movable plate 302, six hydraulic push rods 504 which are uniformly distributed circumferentially are inlaid in the connecting seat 503, when the six hydraulic push rods 504 are all extended to a limit state, the telescopic ends of the six hydraulic push rods 504 are distributed in a step mode, and then the six stirring rods 502 are distributed in a step mode when moving upwards to the limit position, waste water in the reaction tank 2 is layered, the telescopic ends of the six hydraulic push rods 504 are fixedly connected with adjacent connecting blocks 501 respectively, the telescopic ends of the six hydraulic pushrods 504 are used for driving the adjacent connecting blocks 501 to move upwards respectively, so that the six stirring rods 502 are driven to move upwards, the connecting seat 503 is rotationally connected with the liquid storage ring 505, the liquid storage ring 505 is externally connected with a hydraulic pump, the liquid storage ring 505 is rotationally connected with the connecting ring 506 fixedly connected with the connecting seat 503, the connecting ring 506 and the connecting seat 503 are respectively provided with six through holes uniformly distributed in the circumferential direction, the through holes of the connecting ring 506 and the adjacent through holes on the connecting seat 503 are mutually communicated, the fixing parts of the six hydraulic pushrods 504 are respectively provided with the through holes communicated with the connecting ring 506 and the adjacent through holes on the connecting seat 503, and hydraulic oil is conveyed into the liquid storage ring 505 by the hydraulic pump, so that hydraulic oil is conveyed into the fixing parts of the six hydraulic pushrods 504.
After the solution in the reaction tank 2 is layered, a worker starts the second motor 306, the output shaft of the second motor 306 drives the rotation shaft 307 and the scraping plate 308 to synchronously rotate through the transmission of the synchronous belt, the rotation shaft 307 drives the six connecting blocks 501 to synchronously rotate in the rotation process of the rotation shaft 307, the connecting blocks 501 drive the stirring rod 502 to rotate, the stirring rod 502 stirs the mud layer, the mud layer is mixed with the water layer again, the residual oil in the mud layer is contacted with the water layer again, and the residual oil is fused into the oil layer on the upper side upwards, so that the oil content in the mud layer is reduced.
The waste water generated in the petroleum processing process contains partial sulfide besides greasy dirt and silt, and after the oil remained in the mud layer is removed, the sulfide in the waste water can be removed by using the device, and the specific working procedure is as follows:
after the oil remained in the mud layer is removed, the worker stops the second motor 306 and starts the two second electric push rods 301 at the same time, separates the water layer in the reaction tank 2 from the mud layer according to the operation, then starts the gear pump, conveys hydraulic oil to the liquid storage ring 505, drives the six hydraulic push rods 504 to move upwards, and drives the adjacent connecting blocks 501 and the stirring rods 502 connected with the connecting blocks to move upwards respectively at the telescopic ends of the six hydraulic push rods 504 until the telescopic ends of the six hydraulic push rods 504 extend upwards to the limit position, the worker stops the gear pump, at the moment, the vertical positions of the six hydraulic push rods 504 are in stepped distribution, then the worker starts the second motor 306 again while adding calcium hydroxide solution into the reaction tank 2, and drives the six hydraulic push rods 504 to rotate synchronously to stir the solution in the reaction tank 2, so that the mixing speed of the waste water and the calcium hydroxide solution in the reaction tank 2 is accelerated.
Example 3: on the basis of embodiment 2, as shown in fig. 7 and 8, a liquid storage tank 601 is fixedly connected to a supporting frame 1 through a connecting piece, the liquid storage tank 601 is used for storing calcium hydroxide solution, the liquid storage tank 601 is rotationally connected with a rotating shaft 307, the liquid storage tank 601 is communicated with a blind hole on the rotating shaft 307, two fourth electric push rods 602 which are in mirror image type distribution are fixedly connected to the upper side of the liquid storage tank 601, a second push plate 603 is slidingly connected to the inside of the liquid storage tank 601, the telescopic ends of the two fourth electric push rods 602 are fixedly connected with the second push plate 603, a through hole is arranged on the second push plate 603, a one-way valve (which is not shown in the prior device diagram) is arranged in the through hole of the second push plate 603, the two fourth electric push rods 602 drive the second push plate 603 to move up and down together, and when the second push plate 603 moves up, the solution stored in the liquid storage tank 601 is extruded into the rotating shaft 307, the inside of the liquid storage tank 601 is slidably connected with a limiting plate 604 for limiting the volume of the solution in the liquid storage tank 601, a third moving plate 605 is slidably connected in a blind hole of the rotary shaft 307, a connecting rod 606 fixedly connected with the limiting plate 604 is fixedly connected to the third moving plate 605, a cavity filled with heat sensing gas is arranged between the upper part of the rotary shaft 307 and the upper side of the third moving plate 605, when the rotary shaft 307 discharges the calcium hydroxide solution stored in the liquid storage tank 601 into the reaction tank 2, the calcium hydroxide solution reacts with sulfide in the wastewater in the reaction tank 2 and generates heat, the volumes of the heat sensing gas in the cavities of the rotary shaft 307 and the third moving plate 605 are heated to be increased, the third moving plate 605 drives the limiting plate 604 to move downwards through the connecting rod 606 to increase the volume of the calcium hydroxide solution stored in the liquid storage tank 601, the liquid storage tank 601 is externally connected with an input pump, the output pump conveys the calcium hydroxide solution into the liquid storage tank 601, the connecting rod 606 is provided with a through hole, the lower end of the connecting rod 606 is provided with an arc hole, a part of the connecting rod 606, which is close to the second push plate 603, in an initial state is provided with a through hole communicated with the rotating shaft 307, the upper end of the connecting rod 606 penetrates through the rotating shaft 307, the upper end of the connecting rod 606 is externally connected with a gear pump, and the gear pump pumps the residual calcium hydroxide solution in the liquid storage tank 601 and the rotating shaft 307 outwards.
As shown in fig. 7 and fig. 9-11, two groups of second arc baffles 701 are limited and slidingly connected with the rotating shaft 307, each group of second arc baffles 701 is six, which are uniformly distributed circumferentially, the first elastic members 702 fixedly connected with the lower group of second arc baffles 701 are positioned on the same horizontal plane, the heights of the upper group of second arc baffles 701 are the same as the limit positions reached by the adjacent stirring rods 502, the two groups of second arc baffles 701 are respectively matched with the adjacent through holes on the rotating shaft 307, a first elastic member 702 is fixedly connected between the two groups of second arc baffles 701 and the rotating shaft 307, the first elastic members 702 are springs and are used for maintaining the initial positions of the adjacent second arc baffles 701 and driving the moved second arc baffles 701 to reset to the initial positions, the first elastic members 702 fixedly connected with the lower group of second arc baffles 701 are in a compressed state, the blind holes of the six stirring rods 502 are respectively slidingly connected with the moving tubes 703, the six moving tubes 703 are respectively matched with the adjacent through holes on the rotating shaft 307, a first elastic member 702 is fixedly connected with the six moving tubes 703, and the six moving tubes 703 are respectively arranged between the adjacent rotating shaft 307 and the second annular members 704 are respectively arranged between the adjacent rotating shaft 307 and the second annular members 704 in a mutually inclined manner, and the six elastic members are respectively connected with the adjacent elastic members are in an inclined manner, and the rotating shaft 703 is in an inclined manner, and the adjacent elastic members are respectively arranged between the adjacent elastic members are respectively and adjacent to the rotating shafts 704 and are in an inclined state.
After the staff pushes the adjacent stirring rods 502 to the limit positions respectively through the six hydraulic push rods 504, the staff starts the input pump to convey the calcium hydroxide solution into the liquid storage tank 601 until the whole liquid storage tank 601 and the blind holes of the rotating shaft 307 are full of the calcium hydroxide solution, the staff stops the input pump and simultaneously starts the two fourth electric push rods 602, the telescopic ends of the two fourth electric push rods 602 drive the second push rods 603 to move downwards together, in the process that the second push rods 603 move downwards, the calcium hydroxide solution in the liquid storage tank 601 moves upwards through the one-way valves on the through holes of the second push rods until the lower side of the second push rods 603 is contacted with the upper side surfaces of the limiting plates 604, the staff reversely starts the two fourth electric push rods 602, the second push rods 603 reset upwards, the calcium hydroxide solution in the liquid storage tank 601 is extruded into the rotating shaft 307 through the second push rods 603, the calcium hydroxide solution in the rotating shaft 307 is extruded into the six stirring rods, and then the reaction speed of the calcium hydroxide solution in the reaction tank 2 is accelerated.
In the process of upward movement of the six stirring rods 502, the second arc-shaped baffle plates 701 adjacent to the lower side gradually move upward along with the upward movement of the stirring rods 502 under the action of the adjacent first elastic pieces 702, and the through holes on the lower side of the rotating shaft 307 are gradually shielded by the second arc-shaped baffle plates 701 on the lower side, so that when the calcium hydroxide solution is added into the reaction tank 2, the calcium hydroxide solution is prevented from flowing out along the through holes on the lower side of the rotating shaft 307, the concentration of the calcium hydroxide solution on the lower side of the reaction tank 2 is excessively high, and sulfide in wastewater in the reaction tank 2 is incompletely removed.
When the calcium hydroxide solution is added into the reaction tank 2, heat is released along with the reaction of the calcium hydroxide solution and sulfide in the wastewater, the volume of the heat sensitive gas in the cavities of the rotating shaft 307 and the third moving plate 605 is heated to increase, so that the third moving plate 605 drives the connecting rod 606 to move downwards, the connecting rod 606 drives the limiting plate 604 to move downwards synchronously, the volume between the limiting plate 604 and the second pushing plate 603 is increased, the volume of the liquid storage tank 601 is increased, the volume of the calcium hydroxide solution is properly increased, the excessive temperature generated by the reaction tank 2 is avoided when the excessive calcium hydroxide solution is added into the reaction tank 2 for the first time, the sulfide in the wastewater of the reaction tank 2 is gradually consumed along with the gradual consumption of the calcium hydroxide solution when the calcium hydroxide solution is added into the wastewater of the reaction tank 2, the reaction speed of the sulfide and the calcium hydroxide solution in the subsequent reaction tank 2 is reduced, and the time consumed in the reaction process is increased.
In the process of changing the volume of the calcium hydroxide solution to be conveyed into the reaction tank 2, the volume of the calcium hydroxide solution to be firstly added into the reaction tank 2 is the same when the device is used each time, and the concentration of the sulfide contained in the wastewater in the reaction tank 2 can directly influence the reaction speed with the calcium hydroxide solution, so that the heat released by the solution in the reaction tank 2 in a short time can be directly influenced, and the volume of the calcium hydroxide solution to be added into the reaction tank 2 for the second time is influenced.
In the process of stirring the mud layer in the reaction tank 2 by the six stirring rods 502, the demulsifier can be discharged into the mud layer in the reaction tank 2 to accelerate the oil separation speed in the mud layer, the specific operation process is just to refer to the process of adding the calcium hydroxide solution, after the demulsifier is added into the mud layer in the reaction tank 2 each time, the residual demulsifier in the liquid storage tank 601 and the rotating shaft 307 is required to be extracted by using a gear pump, the liquid storage tank 601 and the rotating shaft 307 are cleaned, then the calcium hydroxide solution is added into the reaction tank 2 according to the operation, the normal use of the calcium hydroxide solution is prevented from being influenced by the residual demulsifier in the liquid storage tank 601 and the rotating shaft 307, and the residual calcium hydroxide solution in the liquid storage tank 601 and the rotating shaft 307 is also required to be extracted after the device is used each time, and the normal use of the demulsifier is prevented from being influenced by the residual calcium hydroxide solution in the liquid storage tank 601 and the rotating shaft 307.
The technical principles of the embodiments of the present invention are described above in connection with specific embodiments. The description is only intended to explain the principles of the embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will recognize other embodiments of the present invention without undue burden, and those ways that are within the scope of the present invention.
Claims (5)
1. The utility model provides an industrial waste water recycling device who contains filtration, includes support frame (1), support frame (1) rigid coupling has retort (2), retort (2) detachably are connected with end cover (3) and bottom (4), its characterized in that: the device is characterized by further comprising a conical cover (5), wherein the conical cover (5) is in sealing sliding connection with the reaction tank (2), one side of the end cover (3) close to the bottom cover (4) is fixedly connected with a first electric push rod (6) in mirror image distribution, the telescopic end of the first electric push rod (6) is fixedly connected with one side of the conical cover (5) away from the bottom cover (4), the conical cover (5) is fixedly connected with a water delivery pipe penetrating through the end cover (3), the water delivery pipe of the conical cover (5) is in sliding connection with the end cover (3), a one-way valve is arranged in the water delivery pipe of the conical cover (5), a drain pipe (7) is fixedly connected with the water delivery pipe penetrating through the end cover (3) and in sliding connection with the drain pipe, the drain pipe (7) is communicated with an oil pump, and the water delivery pipe of a filter screen is fixedly connected with the bottom cover (4);
the support frame (1) is fixedly connected with a second electric push rod (301) in mirror image distribution through connecting pieces, the telescopic ends of the second electric push rod (301) in mirror image distribution penetrate through the bottom cover (4) and are in sliding connection with the bottom cover (4), a second movable plate (3041) is fixedly connected with the telescopic ends of the second electric push rod (301) together, a movable shell (303) is fixedly connected and communicated with the reaction tank (2), a fixed plate (304) is fixedly connected with the inside of the movable shell (303) in a sliding manner, the fixed plate (304) is in rotary connection with the second movable plate (302), the fixed plate (304) and the second movable plate (302) are all provided with arc-shaped through holes which are mutually communicated and are in uniform circumferential distribution, the second movable plate (302) is provided with grooves in uniform circumferential distribution, a second interception plate (3041) is fixedly connected in the grooves of the second movable plate (302), a spring is fixedly connected between the second interception plate (3041) and the second movable plate (302), the second interception plate (304) is fixedly connected with the second movable plate (302) through one of the connecting pieces (3041) and is fixedly connected with the water outlet pipe (304) through the connecting piece (3041), the output shaft of the first motor (305) and the movable shell (303) are driven by a transmission assembly;
The support frame (1) is fixedly connected with a second motor (306) through a connecting piece, the end cover (3) is rotationally connected with a rotating shaft (307), the rotating shaft (307) is positioned inside the reaction tank (2), the rotating shaft (307) penetrates through the bottom cover (4), the second movable plate (302) and the fixed plate (304), an output shaft of the second motor (306) and the rotating shaft (307) are transmitted through a synchronous belt, the rotating shaft (307) is slidably connected with a scraping plate (308), the scraping plate (308) is matched with the fixed plate (304), the reaction tank (2) is fixedly connected with a third electric push rod (401) in mirror image distribution through a connecting component, and the telescopic ends of the third electric push rod (401) are fixedly connected with the bottom cover (4) through connecting pieces;
the device is characterized by further comprising connecting blocks (501) which are uniformly distributed circumferentially, wherein the connecting blocks (501) which are uniformly distributed circumferentially are uniformly connected with the rotating shaft (307) in a sliding manner, stirring rods (502) are fixedly connected with the connecting blocks (501) which are uniformly distributed circumferentially, the stirring rods (502) penetrate through the adjacent connecting blocks (501), blind holes which are communicated with each other are formed in the stirring rods (502) and the rotating shaft (307) uniformly distributed circumferentially, through holes which are uniformly distributed axially are formed in the stirring rods (502), one-way valves are arranged in the through holes of the stirring rods (502), the bottom cover (4) is connected with a connecting seat (503) in a sliding manner in a sealing manner, the connecting seat (503) is fixedly connected with the rotating shaft (307), connecting seats (503) are fixedly connected with the second moving plate (302), telescopic ends of the stirring rods (502) which are uniformly distributed circumferentially are fixedly connected with the adjacent connecting blocks (501) respectively, connecting seats (503) are rotatably connected with one another, a connecting ring (505) is connected with a connecting ring (506) in a rotating manner, and the connecting ring (505) is fixedly connected with the connecting ring (506) is fixedly connected with the rotating ring (503), the through holes on the connecting ring (506) are communicated with the adjacent through holes on the connecting seat (503), and the fixing part of the hydraulic push rod (504) is provided with the through holes communicated with the adjacent through holes on the connecting ring (506) and the connecting seat (503);
The support frame (1) is fixedly connected with a liquid storage tank (601) through a connecting piece, the liquid storage tank (601) is rotationally connected with a rotating shaft (307), the liquid storage tank (601) is communicated with a blind hole on the rotating shaft (307), a fourth electric push rod (602) which is distributed in a mirror mode is fixedly connected to one side of the liquid storage tank (601) close to the bottom cover (4), a second push plate (603) is connected to the inner sliding of the liquid storage tank (601) in a sliding mode, telescopic ends of the fourth electric push rod (602) are fixedly connected with the second push plate (603) in a mirror mode, a through hole is formed in the second push plate (603), a one-way valve is arranged in the through hole of the second push plate (603), a limiting plate (604) is connected to the inner sliding of the rotating shaft (307), a connecting rod (606) fixedly connected with the limiting plate (604) is fixedly connected to the blind hole of the rotating shaft (307), one side of the rotating shaft (307) far from the liquid storage tank (601) is far from the connecting rod (606), an arc-shaped air inlet pump (606) is arranged between the connecting rod (606) and the connecting rod (606) is arranged outside the connecting rod (601), one end of the connecting rod (606) close to the second pushing disc (603) is provided with a through hole communicated with the rotating shaft (307), one end of the connecting rod (606) far away from the limiting plate (604) penetrates through the rotating shaft (307), and the connecting rod (606) is externally connected with a gear pump;
The utility model discloses a stirring rod (502) is fixed with a rotary shaft (307), the spacing sliding connection of rotary shaft (307) has circumference evenly distributed's second arc baffle (701), circumference evenly distributed second arc baffle (701) respectively with adjacent through-hole cooperation on rotary shaft (307), circumference evenly distributed second arc baffle (701) all with the rigid coupling has first elastic component (702) between rotary shaft (307), circumference evenly distributed all sliding connection has movable tube (703) in the blind hole of stirring rod (502), movable tube (703) with adjacent through-hole cooperation on rotary shaft (307), just movable tube (703) with the through-hole on rotary shaft (307) all is provided with the slope anchor ring of mutually supporting, movable tube (703) with adjacent rigid coupling has circumference evenly distributed's second elastic component (704) between stirring rod (502).
2. An industrial wastewater reclamation device having a filtering structure according to claim 1, wherein: the utility model discloses a sewage drain pipe (7) rigid coupling and intercommunication have connecting pipe (201), connecting pipe (201) are provided with the spout, connecting pipe (201) sealed sliding connection has first movable plate (202), first movable plate (202) rigid coupling has first arc baffle (203), first arc baffle (203) with spout sliding connection on connecting pipe (201), first movable plate (202) are provided with the through-hole, first movable plate (202) sealed sliding connection has first interception board (204), first interception board (204) with the through-hole cooperation on first movable plate (202), first interception board (204) run through first arc baffle (203) and with its sliding connection, connecting pipe (201) rigid coupling has link (205), link (205) rigid coupling has hydraulic telescoping rod (206), the flexible end of hydraulic telescoping rod (206) with first arc baffle (203) rigid coupling, stock solution link (205) are kept away from one side of sewage drain pipe (7) has first interception board (204), flexible telescoping plate (208) is connected with first push-type push-down plate (209) rigid coupling, flexible disc (208) is connected with first push-down plate (209), the fixed part of the hydraulic telescopic rod (206) is communicated with the liquid storage pipe (208).
3. An industrial wastewater reclamation device having a filtering structure according to claim 2, wherein: the first moving plate (202) and the first intercepting plate (204) each have a density greater than oil and less than water.
4. An industrial wastewater reclamation device having a filtering structure according to claim 1, wherein: the second interception plate (3041) is provided with an inclined surface, and the through hole of the fixed plate (304) is provided with an inclined surface matched with the inclined surface on the adjacent second interception plate (3041).
5. An industrial wastewater reclamation device having a filtering structure according to claim 1, wherein: the size of the through holes uniformly distributed in the axial direction on the stirring rod (502) increases along with the increase of the distance between the stirring rod and the rotating shaft (307).
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CN117815759B (en) * | 2024-03-06 | 2024-05-14 | 辽宁万泽澎建设工程有限公司 | Station forebay filter equipment that water-saving irrigation used |
CN118108318B (en) * | 2024-03-26 | 2024-09-06 | 爱德士鞋业(济宁)有限公司 | Uniform dosing type wastewater treatment equipment for shoemaking factories |
CN118005115B (en) * | 2024-04-08 | 2024-07-09 | 爱德士鞋业(济宁)有限公司 | Materialized treatment device for wastewater of shoemaking factory |
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