CN204454703U - Be applied to the Micro-electrolytic filler structure of high slat-containing wastewater - Google Patents

Abstract

The utility model discloses a micro-electrolysis filler structure applied to high-salt waste water, which includes an inner filler and an outer frame, the inner filler and the outer frame are connected as one through a central connecting bar, and the diameter of the outer frame is larger than that of the inner filler. The inner filler is coaxial with the outer frame, and the outer frame connects two adjacent parallel fillers in the inner filler through a central connecting bar to form a spherical whole. The utility model greatly increases the effective contact area between the waste water and the filler, effectively avoids the agglomeration and hardening of the filler, makes the filler react thoroughly, and greatly improves the wastewater treatment effect; meanwhile, it saves the cumbersome filler flushing link, It only needs to add new filler regularly, which is convenient to implement, reduces the amount of manual operation, reduces the use cost of filler, and further reduces the cost of wastewater treatment.

Description

Micro-electrolytic packing structure applied to high-salt wastewater

technical field

The utility model relates to the technical field of fillers for sewage treatment, in particular to a micro-electrolytic filler structure applied to high-salt wastewater.

Background technique

At present, the discharge of industrial wastewater in our country is very large, and the concentration of COD and BOD is relatively high. In response to this situation, the main technical means adopted by environmental protection companies is to use iron-carbon micro-electrolysis reactors to treat high-COD wastewater. The above-mentioned iron-carbon micro-electrolysis reactor mainly uses micro-electrolysis fillers to treat organic wastewater. In the absence of electricity, the micro-electrolysis material filled in the wastewater generates a 1.2V potential difference to electrolyze the wastewater to achieve organic degradation. purpose of pollutants. The above-mentioned micro-electrolytic fillers are usually made of iron powder and carbon powder. Before use, they need to be activated with acid and alkali. During use, they are easily passivated and compacted. At the same time, iron filings are completely corroded and turned into iron sludge, resulting in micro-electrolytic reactions. If the tank is clogged, flushing is required to alleviate the clogging problem of iron sludge, but flushing cannot solve the problem of declining wastewater treatment effect, and only frequent replacement of new fillers is required. Not only the workload is heavy, but the cost of use is high, and it also affects the treatment effect and efficiency of wastewater.

Utility model content

The purpose of this utility model is to provide a micro-electrolytic packing structure applied to high-salt wastewater to solve the problem that the existing micro-electrolytic packing is easy to passivate and harden, and needs to be replaced frequently, resulting in heavy workload, high use cost, and affecting waste water treatment. Questions of effectiveness and efficiency.

The technical scheme of the utility model is as follows:

A micro-electrolysis packing structure applied to high-salt wastewater, including internal packing and an external frame, characterized in that: the internal packing and the external frame are connected as one by a central connecting bar, and the diameter of the external frame is larger than the The diameter of the inner filler is coaxial with the outer frame, and the outer frame connects two adjacent parallel fillers in the inner filler through the central connecting rod to form a spherical whole.

The micro-electrolysis packing structure applied to high-salt waste water is characterized in that: the side walls of the internal packing are respectively provided with a number of evenly distributed grooves along the circumferential direction, and the internal packing is respectively provided with a number of uniformly distributed grooves. through hole.

The micro-electrolysis filler structure applied to high-salt wastewater is characterized in that: the plurality of grooves are parallel to the axis of the inner filler, and the grooves are gear-shaped.

The micro-electrolysis filler structure applied to high-salt wastewater is characterized in that: the number of the plurality of grooves is 4, 6 or 8.

The micro-electrolysis filler structure applied to high-salt wastewater is characterized in that: the diameter of the outer frame is 70-86mm, and the wall thickness is 2-3mm; the height of the inner filler is 10-12mm, and the diameter is 50-70mm.

The beneficial effects of the utility model:

1. The utility model adopts the structural design of through holes and gear-shaped grooves, which ensures full contact between wastewater and iron-carbon fillers, greatly increases the effective contact area of fillers, and ensures that the fillers always maintain high activity and mass transfer. It can effectively avoid the agglomeration and compaction of traditional micro-electrolytic fillers, make the fillers react thoroughly, and greatly improve the wastewater treatment effect; at the same time, it saves the tedious washing of fillers, and only needs to replenish new fillers regularly, which is convenient for implementation , reducing the amount of manual operations, reducing the cost of using fillers, and further reducing the cost of wastewater treatment.

2. Since iron and carbon are consumed at the same time, and the ratio of iron and carbon will not change during use, the consumption of the micro-electrolytic filler is only a quantitative change, not a qualitative change, so it only needs to be increased with consumption The new micro-electrolytic filler will do.

Description of drawings

Fig. 1 is the overall structural outline drawing of the utility model.

Fig. 2 is a sectional view of the inner center of the utility model.

Fig. 3 is a top view of the inner packing in the utility model.

Fig. 4 is a side view of the inner packing in the utility model.

Detailed ways

Referring to the accompanying drawings, a micro-electrolytic filler structure applied to high-salt wastewater includes an inner filler 2 and an outer frame 1, the inner filler 2 and the outer frame 1 are connected as one by a central connecting bar 3, and the diameter of the outer frame 1 is larger than The diameter of the inner filler 2, the inner filler 2 is coaxial with the outer frame 1, and the outer frame 1 connects two adjacent parallel fillers in the inner filler 2 through the central connecting rod 3 to form a spherical whole.

In the utility model, the side wall of the internal packing 2 is respectively provided with several grooves 4 which are evenly distributed along the circumferential direction, and the internal packing 2 is respectively provided with some through holes 5 which are uniformly distributed; The axes are parallel, and several grooves 4 are respectively gear-shaped; the number of several grooves 4 is 4, 6 or 8; the diameter of the outer frame 1 is 70-86mm, and the wall thickness is 2-3mm; the inner filler 2 has a height of 10-12mm and a diameter of 50-70mm.

The above embodiments are only used to illustrate the technical solutions of the present design, rather than to limit them; although the present design has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that: it can still be described in the foregoing embodiments The recorded technical solutions are modified, or some of the technical features are replaced equivalently; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions of the various embodiments of the design.

Claims (5)

1. A micro-electrolytic packing structure applied to high-salt waste water, comprising internal packing and an external frame, characterized in that: the internal packing and the external frame are connected as one by a central connecting rod, and the diameter of the external frame is Greater than the diameter of the inner filler, the inner filler is coaxial with the outer frame, and the outer frame connects two adjacent parallel fillers in the inner filler through the central connecting rod to form a spherical whole. 2. The micro-electrolytic packing structure applied to high-salt waste water according to claim 1, characterized in that: the sidewall of the internal packing is respectively provided with several grooves evenly distributed along the circumferential direction, and the internal packing is respectively There are several through holes evenly distributed. 3. The micro-electrolysis filler structure applied to high-salt wastewater according to claim 2, characterized in that: the plurality of grooves are parallel to the axis of the inner filler, and the grooves are respectively gear-shaped . 4. The micro-electrolysis filler structure applied to high-salt wastewater according to claim 2, characterized in that: the number of the plurality of grooves is 4, 6 or 8. 5. The micro-electrolysis filler structure applied to high-salt waste water according to claim 1, characterized in that: the diameter of the outer frame is 70-86mm, and the wall thickness is 2-3mm; the height of the inner filler is 10-12mm, with a diameter of 50-70mm.