CN213141495U - Waste water treatment multi-dimensional electrolysis equipment - Google Patents

Abstract

The utility model relates to a waste water treatment multidimensional electrolysis equipment, which comprises an electrolytic bath, wherein a horizontal screen plate is fixedly arranged in the electrolytic bath, a plurality of plate electrodes positioned above the screen plate are detachably arranged in the electrolytic bath, the lower ends of the plate electrodes are contacted with the screen plate, the electrolytic bath positioned above the screen plate is divided into a plurality of filling areas by the plate electrodes, particle electrodes are filled in the filling areas, a plurality of aeration plates are uniformly arranged at intervals on the left and right in the electrolytic bath, the aeration plates are in one-to-one correspondence with the filling areas, the aeration plates are positioned under the corresponding filling areas, and a driving mechanism for driving the aeration plates to swing left and right is arranged on the electrolytic bath; the utility model discloses an aeration board and filler district one-to-one, gaseous aeration hole from the aeration board discharge to the upper impact lie in the particle electrode in the filler district of its top to make the particle electrode spread evenly in corresponding filler district, thereby drive the incessant rotation of drive shaft through driving motor simultaneously and drive aeration board reciprocating swing about, thereby make aeration board no dead angle aeration.

Description

Waste water treatment multi-dimensional electrolysis equipment

Technical Field

The utility model relates to the technical field of wastewater treatment, in particular to a multidimensional electrolysis device for wastewater treatment.

Background

The multidimensional electrolysis technology is based on the traditional flat two-dimensional electrode, particle electrodes are added, namely granular or clastic particle electrodes are filled between a cathode and an anode, the filled particle electrodes are charged through the repolarization effect of an electric field between the cathode and the anode, the surface area of the particle electrodes is greatly increased, so that the surface area ratio of an electrolytic cell is increased, the distance between the filled particle electrodes is small, the water phase mass transfer effect is improved, and the electrolysis efficiency is improved. The particle electrodes of the traditional multidimensional electrolysis equipment are unevenly distributed between the anode plate and the cathode plate, and the electrolysis efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing a waste water treatment multidimension electrolysis equipment, the particle electrode spreads more evenly, and electrolysis is efficient to solve the problem among the prior art.

In order to solve the technical problem, the technical scheme of the utility model is that: the multi-dimensional electrolysis equipment for wastewater treatment comprises an electrolysis bath, wherein a horizontal screen plate is fixedly installed in the electrolysis bath, a plurality of electrode plates positioned above the screen plate are detachably installed in the electrolysis bath, the plurality of electrode plates are uniformly arranged at intervals from left to right, a water inlet pipe positioned below the screen plate is fixedly installed at the left end of the electrolysis bath, and a water outlet pipe positioned above the electrode plates is fixedly installed at the right end of the electrolysis bath; the lower end of the electrode plate is in contact with the screen plate, the electrode plate divides the electrolytic cell above the screen plate into a plurality of filler areas, and the filler areas are filled with particle electrodes; the electrolytic tank is characterized in that a plurality of aeration plates are uniformly arranged in the electrolytic tank at intervals from left to right, the aeration plates correspond to the filler areas one by one, the aeration plates are located under the corresponding filler areas, small shafts extending from front to back are fixedly arranged at the front and back ends of each aeration plate respectively, the small shafts are rotatably connected to the inner wall of the electrolytic tank, cavities are formed in the aeration plates, a plurality of aeration holes communicated with the cavities are uniformly arranged at the tops of the aeration plates at intervals, aeration pipes are arranged at the bottom of the electrolytic tank, one ends of the aeration pipes extend to the outer side of the electrolytic tank and are connected with an air pump, hoses are connected between the aeration plates and the aeration pipes, and a driving mechanism for driving the aeration plates to swing from side to side is arranged on the electrolytic tank.

As a preferable technical scheme, the driving mechanism comprises a gear coaxially and fixedly mounted on the small shaft, the inner sides of the front and rear side walls of the electrolytic cell are respectively and fixedly provided with a slide way extending left and right, a rack is slidably mounted in the slide way, and the rack is meshed with the gears at the corresponding ends of the plurality of aeration plates; a spring is connected between the left end of the rack and the inner wall of the electrolytic cell, a push rod extending in the same direction is fixedly installed at the right end of the rack, and the push rod extends rightwards to the outer side of the electrolytic cell; two backup pads are fixedly installed relatively around the right side of electrolysis trough, two the drive shaft that extends around rotating to install between the backup pad, fixed mounting have with the eccentric wheel of push rod one-to-one in the drive shaft, the right-hand member of push rod supports correspondingly on the outer peripheral face of eccentric wheel, one of them fixed mounting has and is used for driving in the backup pad drive shaft pivoted driving motor.

As the preferred technical scheme, the right side wall of the electrolytic cell is provided with an avoiding hole for the push rod to pass through, and the inner wall of the avoiding hole is provided with a sealing rubber pad.

As a preferable technical scheme, the electrode plate comprises an anode plate and a cathode plate, and the anode plate and the cathode plate are arranged in a staggered mode.

Preferably, a plurality of vertically extending sliding grooves are respectively and uniformly arranged on the left and right sides of the inner sides of the front and rear side walls of the electrolytic cell at intervals, and the electrode plate is slidably mounted between the two sliding grooves which are opposite in the front and rear direction.

By adopting the technical scheme, the multidimensional electrolysis equipment for wastewater treatment comprises an electrolysis bath, wherein a horizontal screen plate is fixedly arranged in the electrolysis bath, a plurality of electrode plates are detachably arranged in the electrolysis bath, the electrode plates divide the electrolysis bath above the screen plate into a plurality of filler zones, particle electrodes are filled in the filler zones, a plurality of aeration plates are uniformly arranged in the electrolysis bath at intervals from left to right, the aeration plates correspond to the filler zones one by one, and a driving mechanism for driving the aeration plates to swing from left to right is arranged on the electrolysis bath; the utility model discloses an aeration board and filler district one-to-one, gaseous aeration hole from the aeration board discharge to the upper impact lie in the particle electrode in the filler district of its top to make the particle electrode spread evenly in corresponding filler district, thereby it drives the incessant rotation of drive shaft and drives aeration board reciprocating swing about driving simultaneously through driving motor, thereby makes aeration board no dead angle aeration, more is favorable to improving the dispersion effect of particle electrode, improves electrolysis efficiency.

Drawings

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

Fig. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic sectional view A-A of FIG. 1;

fig. 3 is a schematic sectional view of B-B in fig. 2.

In the figure: 1-an electrolytic cell; 2-screen plate; 3-an electrode plate; 301-an anode plate; 302-a cathode plate; 4-water inlet pipe; 5-water outlet pipe; 6-a packing zone; 7-a particle electrode; 8-an aeration plate; 9-small shaft; 10-a cavity; 11-aeration holes; 12-an aerator pipe; 13-an air pump; 14-a hose; 15-gear; 16-a slide; 17-a rack; 18-a spring; 19-a push rod; 20-a support plate; 21-a drive shaft; 22-eccentric wheel; 23-a drive motor; 24-avoiding holes; 25-sealing rubber gasket; 26-chute.

Detailed Description

As shown in fig. 1 to 3, the multi-dimensional wastewater treatment electrolysis device comprises an electrolysis bath 1, wherein a horizontal screen plate 2 is fixedly installed in the electrolysis bath 1, a plurality of electrode plates 3 positioned above the screen plate 2 are detachably installed in the electrolysis bath 1, the plurality of electrode plates 3 are uniformly arranged at intervals from left to right, specifically, the electrode plates 3 comprise anode plates 301 and cathode plates 302, and the anode plates 301 and the cathode plates 302 are arranged in a staggered manner; a water inlet pipe 4 positioned below the screen plate 2 is fixedly installed at the left end of the electrolytic cell 1, and a water outlet pipe 5 positioned above the electrode plate 3 is fixedly installed at the right end of the electrolytic cell 1; the lower end of the electrode plate 3 is in contact with the screen plate 2, the electrode plate 3 divides the electrolytic cell 1 above the screen plate 2 into a plurality of filler areas 6, and the filler areas 6 are filled with particle electrodes 7; the electrolytic cell comprises an electrolytic cell 1 and is characterized in that a plurality of aeration plates 8 are uniformly arranged in the electrolytic cell 1 at intervals left and right, the aeration plates 8 correspond to the filler regions 6 one by one, the aeration plates 8 are located under the corresponding filler regions 6, small shafts 9 extending from front to back are respectively fixedly arranged at the front ends and the rear ends of the aeration plates 8, the small shafts 9 are rotatably connected to the inner wall of the electrolytic cell 1, cavities 10 are formed in the aeration plates 8, a plurality of aeration holes 11 communicated with the cavities 10 are uniformly arranged at the tops of the aeration plates 8 at intervals, aeration pipes 12 are arranged at the bottom of the electrolytic cell 1, one ends of the aeration pipes 12 extend to the outer side of the electrolytic cell 1 and are connected with air pumps 13, hoses 14 are connected between the aeration plates 8 and the aeration pipes 12, and a driving mechanism for driving the aeration plates 8 to swing left and right is arranged on the electrolytic cell 1.

When the device is used, the anode plate 301 and the cathode plate 302 are respectively connected with the anode and the cathode of a power supply, wastewater is injected into the electrolytic tank 1 through the water inlet pipe 4, and the wastewater passes through the anode plate 301, the cathode plate 302 and the particle electrode 7 upwards after entering the electrolytic tank 1 to generate multi-dimensional electrolysis and is finally discharged from the water outlet pipe 5; in the process, the air pump 13 pumps air into the cavity 10 of the aeration plate 8 through the aeration pipe 12, and the air is discharged from the aeration holes 11 of the aeration plate 8 and then impacts the particle electrodes 7 in the filler zone 6 above the aeration plate, so that the particle electrodes 7 are uniformly diffused in the corresponding filler zones, and the particle electrodes 7 are prevented from being accumulated on the screen plate 2.

The driving mechanism comprises a gear 15 coaxially and fixedly installed on the small shaft 9, slide ways 16 extending left and right are respectively and fixedly installed on the inner sides of the front side wall and the rear side wall of the electrolytic cell 1, racks 17 are installed in the slide ways 16 in a sliding manner, and the racks 17 are meshed with the gears 15 at the corresponding ends of the aeration plates 8; a spring 18 is connected between the left end of the rack 17 and the inner wall of the electrolytic cell 1, a push rod 19 extending in the same direction is fixedly mounted at the right end of the rack 17, and the push rod 19 extends rightwards to the outer side of the electrolytic cell 1; two supporting plates 20 are fixedly mounted on the right side of the electrolytic cell 1 in a front-back opposite mode, a driving shaft 21 extending from front to back is rotatably mounted between the two supporting plates 20, eccentric wheels 22 in one-to-one correspondence with the push rods 19 are fixedly mounted on the driving shaft 21, the right ends of the push rods 19 abut against the outer peripheral surfaces of the eccentric wheels 22 correspondingly, and a driving motor 23 used for driving the driving shaft 21 to rotate is fixedly mounted on one of the supporting plates 20.

The driving shaft 21 is driven to rotate by the driving motor 23, the eccentric wheel 22 is driven to rotate by the driving shaft 21, when the side, far away from the driving shaft 21, of the outer peripheral surface of the eccentric wheel 22 rotates to be in contact with the push rod 19, the eccentric wheel 22 drives the rack 17 to move leftwards along the slide way 16 through the push rod 19 and compress the spring 18, the gear 15 and the small shaft 9 are driven to rotate clockwise when the rack 17 moves leftwards, and the small shaft 9 drives the aeration plate 8 to swing rightwards; when the side, close to the driving shaft 21, of the outer peripheral surface of the eccentric wheel 22 rotates to be in contact with the push rod 19, the spring 18 in a compressed state stretches and drives the rack 17 to move rightwards along the slideway 16, when the rack 17 moves rightwards, the gear 15 and the small shaft 9 are driven to rotate anticlockwise, and the small shaft 9 drives the aeration plate 8 to swing leftwards; the driving motor 23 drives the driving shaft 21 to rotate ceaselessly so as to drive the aeration plate 8 to swing left and right in a reciprocating manner, so that the aeration plate 8 can perform aeration without dead angles, and the dispersion effect of the particle electrode 7 is improved.

Be equipped with on the right side wall of electrolysis trough 1 and supply dodge hole 24 that push rod 19 passed, be equipped with sealing rubber pad 25 on the inner wall of dodging hole 24 for improve the leakproofness between dodging hole 24 and push rod 19.

The inboard of the front and back lateral wall of electrolysis trough 1 is equipped with a plurality of vertical extension's spout 26 about evenly spaced respectively, electrode plate 3 slidable mounting is relative two in the front and back between the spout 26 for conveniently dismantle electrode plate 3.

The basic principles, main features and advantages of the present invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. Waste water treatment multidimension electrolysis equipment, its characterized in that: the electrolytic cell comprises an electrolytic cell, wherein a horizontal screen plate is fixedly arranged in the electrolytic cell, a plurality of electrode plates positioned above the screen plate are detachably arranged in the electrolytic cell, the plurality of electrode plates are uniformly arranged at intervals from left to right, a water inlet pipe positioned below the screen plate is fixedly arranged at the left end of the electrolytic cell, and a water outlet pipe positioned above the electrode plates is fixedly arranged at the right end of the electrolytic cell; the lower end of the electrode plate is in contact with the screen plate, the electrode plate divides the electrolytic cell above the screen plate into a plurality of filler areas, and the filler areas are filled with particle electrodes; the electrolytic tank is characterized in that a plurality of aeration plates are uniformly arranged in the electrolytic tank at intervals from left to right, the aeration plates correspond to the filler areas one by one, the aeration plates are located under the corresponding filler areas, small shafts extending from front to back are fixedly arranged at the front and back ends of each aeration plate respectively, the small shafts are rotatably connected to the inner wall of the electrolytic tank, cavities are formed in the aeration plates, a plurality of aeration holes communicated with the cavities are uniformly arranged at the tops of the aeration plates at intervals, aeration pipes are arranged at the bottom of the electrolytic tank, one ends of the aeration pipes extend to the outer side of the electrolytic tank and are connected with an air pump, hoses are connected between the aeration plates and the aeration pipes, and a driving mechanism for driving the aeration plates to swing from side to side is arranged on the electrolytic tank.

2. The wastewater treatment multi-dimensional electrolysis apparatus according to claim 1, wherein: the driving mechanism comprises a gear which is coaxially and fixedly installed on the small shaft, the inner sides of the front side wall and the rear side wall of the electrolytic cell are respectively and fixedly provided with a slideway which extends leftwards and rightwards, a rack is arranged in the slideway in a sliding manner, and the rack is meshed with the gears at the corresponding ends of the plurality of aeration plates; a spring is connected between the left end of the rack and the inner wall of the electrolytic cell, a push rod extending in the same direction is fixedly installed at the right end of the rack, and the push rod extends rightwards to the outer side of the electrolytic cell; two backup pads are fixedly installed relatively around the right side of electrolysis trough, two the drive shaft that extends around rotating to install between the backup pad, fixed mounting have with the eccentric wheel of push rod one-to-one in the drive shaft, the right-hand member of push rod supports correspondingly on the outer peripheral face of eccentric wheel, one of them fixed mounting has and is used for driving in the backup pad drive shaft pivoted driving motor.

3. The wastewater treatment multi-dimensional electrolysis apparatus according to claim 2, wherein: the right side wall of the electrolytic cell is provided with an avoiding hole for the push rod to pass through, and the inner wall of the avoiding hole is provided with a sealing rubber pad.

4. The wastewater treatment multi-dimensional electrolysis apparatus according to claim 1, wherein: the electrode plate comprises an anode plate and a cathode plate, and the anode plate and the cathode plate are arranged in a staggered mode.

5. The wastewater treatment multi-dimensional electrolysis apparatus according to claim 1, wherein: the inner sides of the front and rear side walls of the electrolytic cell are respectively provided with a plurality of vertically extending sliding grooves at equal intervals from left to right, and the electrode plate is slidably arranged between the two sliding grooves which are opposite in the front and the rear.

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