CN213085507U - Nanometer microbubble high-concentration organic wastewater treatment system - Google Patents

Abstract

The application relates to a nanometer microbubble high concentration organic wastewater treatment system, it includes the wastewater disposal basin that holds waste water, sets up the nanometer microbubble generator in the wastewater disposal basin bottom and to the air compressor machine of nanometer microbubble generator air feed, the wastewater disposal basin is the upper shed structure, the port of giving vent to anger of air compressor machine and the intake pipe of nanometer microbubble generator are provided with first hose, and the one end of first hose communicates in the port of giving vent to anger of air compressor machine, and the other end communicates the intake pipe of nanometer microbubble generator, is provided with the second hose on the inlet tube of nanometer microbubble generator, the one end of second hose communicates external water source, and the other end communicates nanometer microbubble generator; the aeration pipe of the nanometer microbubble generator faces the opening direction of the wastewater tank, a displacement device for changing the position of the nanometer microbubble generator is fixed on the wastewater tank, and the nanometer microbubble generator is fixed on the displacement device. This application has easy maintenance's effect.

Description

Nanometer microbubble high-concentration organic wastewater treatment system

Technical Field

The application relates to the technical field of wastewater treatment, in particular to a nanometer microbubble wastewater treatment system.

Background

At present, the nanometer microbubble is the superfine microbubble that the diameter is less than 50 microns, and nanometer microbubble is ascending speed slow, dwell time is long, the dissolution efficiency is high in aqueous to possess characteristics such as oxygenation certainly, take the negative charge and be rich in strong oxidizing property's free radical, thereby nanometer microbubble can produce certain high temperature in the rupture process and destroy the structure of filth, and drive the filth come-up to the liquid level.

Present, most nanometer microbubble generator all places in the bottom of wastewater disposal basin, provides nanometer microbubble in to the wastewater disposal basin, and the air compressor machine that provides compressed gas for nanometer microbubble generator is fixed in the top or other positions of wastewater disposal basin, when needs carry out maintenance to nanometer microbubble, need shut down discharge sewage and utilize extra lifting device to promote nanometer microbubble generator.

With respect to the related art described above, the inventors consider that there is a drawback that maintenance is inconvenient.

SUMMERY OF THE UTILITY MODEL

In order to improve the inconvenient problem of maintenance, the application provides a nanometer microbubble high concentration organic waste water treatment system.

The application provides a nanometer microbubble high concentration organic wastewater treatment system adopts following technical scheme:

a nanometer microbubble high-concentration organic wastewater treatment system comprises a wastewater pool for containing wastewater, a nanometer microbubble generator arranged at the bottom of the wastewater pool and an air compressor for supplying air to the nanometer microbubble generator, wherein the wastewater pool is of an upper opening structure, an air outlet port of the air compressor and an air inlet pipe of the nanometer microbubble generator are provided with a first hose, one end of the first hose is communicated with the air outlet port of the air compressor, the other end of the first hose is communicated with the air inlet pipe of the nanometer microbubble generator, a second hose is arranged on an water inlet pipe of the nanometer microbubble generator, one end of the second hose is communicated with an external water source, and the other end of the second hose is communicated with the nanometer microbubble generator;

the aeration pipe of the nanometer microbubble generator faces the opening direction of the wastewater tank, and a displacement device for changing the position of the nanometer microbubble generator is fixed on the wastewater tank.

By adopting the technical scheme, the first hose and the second hose can not obstruct the lifting motion when the nanometer microbubble generator and the displacement device are lifted; nanometer microbubble generator is fixed in displacement device and on the bottom of wastewater disposal basin, can handle the organic waste water of high concentration in the wastewater disposal basin, and nanometer microbubble generator's screen pipe sets up towards the opening of wastewater disposal basin, and nanometer microbubble can slowly rebound, can the vortex on the one hand, and on the other hand will contact more waste water, improves waste water treatment efficiency, when promoting to above the liquid level, can stand to maintain through supplying staff such as setting up pedestrian's passageway on the wastewater disposal basin and repair.

Preferably, the displacement device comprises two slide rails vertically fixed on two sides of the wastewater tank respectively and a working guide rail connected to the two slide rails in a sliding manner, the working guide rail comprises two sub guide rails parallel to each other, and the sub guide rails are perpendicular to the slide rails; the slide rail includes two mutually parallel subrails, and is same two subrails of slide rail are located the same lateral wall of wastewater disposal basin, one divide the subrail of sliding connection on the different lateral walls of wastewater disposal basin that the guide rail corresponds, the wastewater disposal basin extends to the slide rail, work guide rail perpendicular to slide rail, displacement device still includes the hoist mechanism who is used for vertical promotion work guide rail.

Through adopting above-mentioned technical scheme, be fixed in the slide rail on the wastewater disposal basin lateral wall and slide and connect the work guide rail on the slide rail and will drive nanometer microbubble generator and carry out vertical removal, promote nanometer microbubble generator above the liquid level.

Preferably, the slide rail transversely is provided with the slide of horizontal extension in the one end that extends the wastewater disposal basin, slide butt in the border of wastewater disposal basin, on the same lateral wall of wastewater disposal basin set up the spout that supplies the slide to slide on the sub-rail, be located two on the slide rail of the same lateral wall of wastewater disposal basin the opening of spout sets up in opposite directions, the slide slides and connects in the slide rail, the slide is kept away from nanometer microbubble generator's one end and can be dismantled and be connected with the anchor post, the anchor post is pegged graft in the border of wastewater disposal basin.

By adopting the technical scheme, the sliding plates mainly have the functions of enabling pedestrians to walk to approach and maintain the nanometer microbubble generator, the sliding plates which are connected with the sliding rails in a sliding mode are also respectively positioned on two sides of the wastewater pool, the two sliding plates slide to be mutually abutted, a complete channel is formed, and at the moment, an extra pedestrian channel is not even needed; the anchor post can be fixed the slide on the one hand, can reduce the probability that the slide rotated the skew on the one hand.

Preferably, the both sides that the slide is on a parallel with the work guide rail are provided with the railing of vertical extension, the railing is located the one side that the slide deviates from the wastewater disposal basin border.

Through adopting above-mentioned technical scheme, when the staff walked, in order to guarantee staff's walking safety, set up the railing and protect, avoid the staff foot to slide in to the waste water pond.

Preferably, the lower part of nanometer microbubble generator is fixed with a plurality of branches, the one end of branch is fixed in on the work guide rail, and the other end is fixed in the lower part of nanometer microbubble generator, branch is located the opposite side of two railings.

Through adopting above-mentioned technical scheme, branch makes nanometer microbubble generator be located work guide rail top take the altitude, and the staff can observe and overhaul nanometer microbubble generator's bottom this moment, if nanometer microbubble generator is less than apart from work guide rail's height, is unfavorable for the staff to carry out the holistic maintenance of nanometer microbubble generator.

Preferably, a through groove which vertically penetrates through two sides of the sliding plate is formed in the sliding plate, the opening direction of the through groove faces to the center of the wastewater pond, and the support rod is connected to the through groove in a sliding mode.

Through adopting above-mentioned technical scheme, the slide of sliding connection on the slide rail is located the both sides of wastewater disposal basin respectively equally, and two slides slide when with mutual butt, and it can receive the interference of branch, consequently sets up logical groove, avoids the stopping of branch to the slide.

Preferably, a limiting sliding groove is fixed on one side, away from the bottom wall of the wastewater pool, of the working guide rail, the limiting sliding groove extends along the length direction of the working guide rail, and the limiting sliding groove is connected to the sliding plate in a sliding mode.

Through adopting above-mentioned technical scheme, mainly be in order to improve the stable overlap joint of slide on the work guide rail, also can restrict the slide and take place certain skew in the horizontal direction simultaneously, safety guarantee when improving the maintenance, when the slide slides towards the wastewater disposal basin center and slides, two slides butt each other, form a passageway that supplies the staff to walk about.

Preferably, a vertically extending baffle is fixed on the guardrail bar, and one side of the baffle, which is close to the bottom wall of the wastewater pond, abuts against the sliding plate.

Through adopting above-mentioned technical scheme, when the maintenance, the staff can be the reason such as the hand is smooth, and repair tools can drop on the slide, has the probability that drops in the wastewater disposal basin this moment, consequently sets up vertical baffle, and one side butt of baffle is in the slide, reduces the probability that the instrument dropped in the wastewater disposal basin.

Preferably, hoist mechanism includes the electric hoist, extends the wastewater disposal basin one end slope at the slide rail and is fixed with a plurality of lift bars, and the one end that the slide rail was kept away from to a plurality of lift bars is drawn close each other and is fixed, the electric hoist is fixed in the interconnect department of a plurality of lift bars be fixed with the lug on the work guide rail, the lifting hook of electric hoist is connected in the lug.

Through adopting above-mentioned technical scheme, provide vertical movement's power to the displacement device through hoist mechanism, drive the work guide rail and carry out vertical movement, lug and electric hoist on the work guide rail are connected to it carries out vertical movement along the slide rail to drive the work guide rail.

In summary, the present application includes at least one of the following beneficial technical effects:

this application utilizes hoist mechanism to promote displacement device on being fixed in displacement device with nanometer microbubble generator, at this moment, need not discharge still unpurified waste water, also need not hoist and mount nanometer microbubble generator to other places, can directly maintain in the top of wastewater disposal basin.

Drawings

Fig. 1 is a schematic view of the overall structure of the present application in a use state.

Fig. 2 is a schematic diagram of the overall structure of the application after being upgraded.

Fig. 3 is a partial structural schematic diagram of the displacement device of the present application.

FIG. 4 is a schematic view of the construction of the lower portion of the working rail of the present application

FIG. 5 is a schematic view of the upper structure of the working rail of the present application

Description of reference numerals: 1. a wastewater tank; 2. a nano-microbubble generator; 3. an air compressor; 41. a first hose; 42. a second hose; 51. a slide rail; 511. a sub-track; 5112. a chute; 52. a working guide rail; 521. dividing guide rails; 522. lifting lugs; 53. a strut; 54. a restricting chute; 61. a slide plate; 611. a through groove; 62. an anchor post; 63. a railing; 64. a baffle plate; 71. an electric hoist; 72. a lifting rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses nanometer microbubble high concentration organic wastewater treatment system. Referring to fig. 1 and 2, the nano-microbubble high-concentration organic wastewater treatment system includes a nano-microbubble generator 2, an air compressor 3 for supplying air to the nano-microbubble generator 2, and a wastewater tank 1 for containing high-concentration organic wastewater, a first hose 41 for communicating the air compressor 3 and the nano-microbubble generator 2 is provided between the air compressor 3 and the nano-microbubble generator 2, one end of the first hose 41 is communicated with an air inlet pipe of the nano-microbubble generator 2, and the other end is communicated with an air outlet pipe of the air compressor 3; a water inlet pipe of the nano-micro-bubble generator 2 is communicated with a second hose 42, one end of the second hose 42 is communicated with an external water source, and the other end is communicated with the nano-micro-bubble generator 2; also comprises a displacement device arranged in the wastewater tank 1.

The air compressor 3 provides gas to the nanometer microbubble generator 2, and the external water source provides water to the nanometer microbubble generator 2, and the nanometer microbubble generator 2 produces a large amount of nanometer microbubbles.

The nanometer microbubble generator 2 is located at the bottom of the wastewater tank 1, the wastewater tank 1 is of an upper opening structure, and an aeration pipe of the nanometer microbubble generator 2 faces the opening direction of the wastewater tank 1 and is located below the liquid level.

Nanometer microbubble generator 2 carries out purification treatment to the waste water in the wastewater disposal basin 1, and nanometer microbubble generator 2's aeration pipe provides nanometer microbubble to wastewater disposal basin 1 in, and nanometer microbubble slowly moves up, when nanometer microbubble broke, can send certain heat to be done purification treatment to the high concentration organic waste water in the wastewater disposal basin 1.

The displacement device comprises slide rails 51 fixed on two opposite side walls of the wastewater tank 1 and working guide rails 52 arranged on the two slide rails 51, the working guide rails 52 are perpendicular to the slide rails 51, the slide rails 51 vertically extend out of the wastewater tank 1, the working guide rails 52 are connected to the slide rails 51 on two opposite side walls of the wastewater tank in a sliding manner at the same time, the working guide rails 52 comprise two sub-guide rails 521 which are parallel to each other, the slide rails 51 comprise two sub-rails 511 which are parallel to each other, two ends of one sub-guide rail 521 are connected to the sub-rails 511 on different side walls of the wastewater tank 1 in a sliding manner, connecting rods which are perpendicular to the two sub-rails 511 at the same time are fixed on opposite sides of the two sub-rails 511 which are parallel to each other, and the two independent sub-rails 511 are connected into; and also enhances the overall structural strength of the working rail 52.

The slide rail 51 may enable the working rail 52 to move vertically, so as to drive the nano micro bubble generator 2 to move vertically.

A plurality of supporting rods 53 are vertically fixed on the working guide rail 52, one end of each supporting rod 53 is fixed on the working guide rail 52, the other end of each supporting rod 53 is fixed at the lower part of the nano-micro-bubble generator 2, and each supporting rod 53 is positioned on one side of the working guide rail 52, which is far away from the bottom wall of the wastewater tank 1; the strut 53 makes the nano-micro-bubble generator 2 higher than the working guide rail 52, so that the bottom of the nano-micro-bubble generator 2 can be overhauled by the staff, and maintenance is convenient.

Referring to fig. 2, the displacement device further includes a lifting mechanism for vertically lifting the working rail 52, the lifting mechanism includes an electric hoist 71, a plurality of lifting lugs 522 are fixed on one side of the working rail 52, which is far away from the bottom wall of the wastewater disposal basin 1, a lifting hook of the electric hoist 71 is connected to the lifting lugs 522, and the lifting hook of the electric hoist 71 can lift the working rail for lifting, so as to drive the nano micro-bubble generator 2 to perform vertical movement.

Referring to fig. 2 and 3, the opposite sides of the two sub-rails 511 on the same side wall of the wastewater pond 1 are provided with sliding grooves 5112, the openings of the two corresponding sliding grooves 5112 are arranged in opposite directions, the sliding grooves 5112 are positioned at the position of the horizontal plane of the sub-rails 511 at the edge of the wastewater pond 1, and sliding plates 61 for people to walk are connected in the two corresponding sliding grooves 5112 in a sliding manner.

The sliding plate 61 abuts against the soil layer at the edge of the wastewater pool 1, one end of the sliding plate 61, which is far away from the nano micro-bubble generator 2, is detachably connected with the anchor column 62, and the anchor column 62 is inserted at the edge of the wastewater pool 1; after two slides 61 carry out the butt, can insert anchor post 62 in the border of wastewater disposal basin 1, and then make two slides 61's rigidity, prevent that personnel from walking about last, take place the skew along slide 61's length direction, simultaneously, anchor post 62 can also carry out the fixed to slide 61 for slide 61 is more firm fixes the border at wastewater disposal basin 1.

Referring to fig. 4, the sliding plate 61 is provided with a through groove 611 vertically penetrating through two sides of the sliding plate 61, an opening direction of the through groove 611 faces to the center of the wastewater disposal basin 1, and the support rod 53 is connected to the through groove 611 in a sliding manner.

Two slides 61 are promoted by the staff in order to do the motion in opposite directions, and when slide 61 met branch 53, branch 53 slided in logical groove 611, can not hinder two slides 61 and carry out the butt, and when two slides 61 butt each other, formed the passageway that supplies personnel to walk at last, made things convenient for personnel to walk on it.

Referring to fig. 5, rails 63 are vertically fixed on two sides of the sliding plate 61 parallel to the working guide rail 52, the rails 63 are located on one side of the sliding plate 61, which is vertically far away from the wastewater tank 1, and the supporting rods 53 are located in the opposite side of the rails 63; the rail 63 prevents workers from falling into the waste 1.

A baffle plate 64 is fixed on the rail 63, the baffle plate 64 extends along the length direction of the sliding plate 61, one side of the baffle plate 64, which is close to the wastewater pool 1, abuts against the sliding plate 61, and the baffle plate 64 can reduce the probability that a maintenance tool falls into the wastewater pool 1.

Referring to fig. 3 and 5, in order to fix the position of the sliding plate 61 more stably and reduce the vertical deformation of the sliding plate 61 caused by the weight of the working personnel, a limiting chute 54 is fixed on one side of the sub-guide rail 521 away from the wastewater tank 1, the limiting chute 54 is connected to the sliding plate 61 in a sliding manner, the openings of the limiting chutes 54 on the two sub-guide rails 521 are arranged oppositely, and the limiting chutes 54 extend along the length direction of the working guide rail 52; on one hand, the limiting chute 54 provides a certain vertical supporting force to the sliding plate 61 to prevent the sliding plate 61 from bending vertically, and on the other hand, can also limit the sliding plate 61 from shifting horizontally.

The implementation principle of the nanometer microbubble high-concentration organic wastewater treatment system in the embodiment of the application is as follows:

firstly, when maintenance is needed, the electric hoist 71 is started to lift the working guide rail to the same height of the edge of the wastewater pool 1;

secondly, the sliding plates 61 on the two side walls of the sliding wastewater pool 1 enable the sliding plates 61 to be lapped on the working guide rail 52, the two sliding plates 61 are abutted to form a channel, and a worker can walk on the sliding plates 61 to maintain the nanometer micro-bubble generator 2

Finally, after the maintenance is completed, the anchor post 62 is taken out, the sliding plate 61 is drawn out, and the nano micro-bubble generator 2 descends through the electric hoist 71 until the working guide rail 52 descends to the bottom of the wastewater tank 1.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a nanometer microbubble high concentration organic wastewater treatment system, is including wastewater disposal basin (1) that holds waste water, setting at nanometer microbubble generator (2) of wastewater disposal basin (1) bottom and to air compressor machine (3) of nanometer microbubble generator (2) air feed, wastewater disposal basin (1) is the upper shed structure, its characterized in that: a first hose (41) is arranged at an air outlet port of the air compressor (3) and an air inlet pipe of the nanometer micro-bubble generator (2), one end of the first hose (41) is communicated with the air outlet port of the air compressor (3), the other end of the first hose is communicated with the air inlet pipe of the nanometer micro-bubble generator (2), a second hose (42) is arranged on an water inlet pipe of the nanometer micro-bubble generator (2), one end of the second hose (42) is communicated with an external water source, and the other end of the second hose is communicated with the nanometer micro-bubble generator (2);

the aeration pipe of nanometer microbubble generator (2) is towards the opening direction of wastewater disposal basin (1), is fixed with the displacement device that is used for changing nanometer microbubble generator (2) position on wastewater disposal basin (1), nanometer microbubble generator (2) are fixed in on the displacement device.

2. The system for treating high-concentration organic wastewater containing microbubbles according to claim 1, wherein: the displacement device comprises two sliding rails (51) which are vertically fixed on two sides of the wastewater tank respectively and a working guide rail (52) which is connected to the two sliding rails (51) in a sliding mode simultaneously, the working guide rail (52) comprises two parallel sub guide rails (521), and the sub guide rails (521) are perpendicular to the sliding rails (51); slide rail (51) include two mutually parallel subrail (511), it is same two subrail (511) of slide rail (51) are located same lateral wall of wastewater disposal basin (1), one divide guide rail (521) to slide and connect corresponding subrail (511) on the different lateral walls of wastewater disposal basin (1), slide rail (51) extend wastewater disposal basin (1), work guide rail (52) perpendicular to slide rail (51) just nanometer microbubble generator (2) are fixed in on work guide rail (52), displacement device is still including being used for vertical hoist mechanism who promotes work guide rail (52) vertical migration.

3. The system for treating high-concentration organic wastewater containing microbubbles according to claim 2, wherein: slide rail (51) extend the one end of wastewater disposal basin (1) and transversely be provided with slide (61) of horizontal extension, one side butt in the soil layer at the border of wastewater disposal basin (1) offer spout (5112) that supply slide (61) to slide on sub-rail (511) on the same lateral wall of wastewater disposal basin (1), be located the opening of two spout (5112) on sub-rail (511) of the same lateral wall of wastewater disposal basin (1) sets up in opposite directions, the one end that nanometer microbubble generator (2) were kept away from in slide (61) can be dismantled and be connected with a plurality of anchor posts (62), anchor post (62) are pegged graft in the border of wastewater disposal basin (1).

4. The system for treating high-concentration organic wastewater containing microbubbles according to claim 3, wherein: the sliding plate (61) is parallel to two sides of the working guide rail (52) and is provided with a vertically extending rail (63), and the rail (63) is positioned on one side of the sliding plate (61) departing from the edge of the wastewater pond (1).

5. The system for treating high-concentration organic wastewater containing microbubbles according to claim 4, wherein: the lower part of nanometer microbubble generator (2) is fixed with a plurality of branches (53), on the one end of branch (53) was fixed in work guide rail (52), the other end was fixed in the lower part of nanometer microbubble generator (2), branch (53) are located the opposite side of two railing (63).

6. The system for treating high-concentration organic wastewater containing microbubbles according to claim 5, wherein: the sliding plate (61) is provided with a through groove (611) vertically penetrating through two sides of the sliding plate (61), the opening direction of the through groove (611) faces to the center of the wastewater disposal basin (1), and the support rod (53) is connected to the through groove (611) in a sliding mode.

7. The system for treating high-concentration organic wastewater containing microbubbles according to claim 6, wherein: and a limiting sliding chute (54) is fixed on one side of the working guide rail (52) departing from the bottom wall of the wastewater tank (1), the limiting sliding chute (54) extends along the length direction of the working guide rail (52), and the sliding plate (61) is connected to the limiting sliding chute (54) in a sliding manner.

8. The system for treating high-concentration organic wastewater containing microbubbles according to claim 7, wherein: a vertically extending baffle plate (64) is fixed on the guardrail bar (63), and one side of the baffle plate (64) close to the bottom wall of the wastewater pond (1) is abutted against the sliding plate (61).

9. The system for treating high-concentration organic wastewater containing microbubbles according to claim 8, wherein: the lifting mechanism comprises an electric hoist (71), a plurality of lifting rods (72) are obliquely fixed to one end of the sliding rail (51) extending out of the wastewater disposal basin (1), one ends of the lifting rods (72) far away from the sliding rail (51) are close to each other and fixed, the electric hoist (71) is fixed to the interconnection positions of the lifting rods (72), lifting lugs (522) are fixed to the working guide rail (52), and lifting hooks of the electric hoist (71) are connected to the lifting lugs (522).

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