阅读说明：本技术 一种应用于放射性工业废水的处理控制方法 (Treatment control method applied to radioactive industrial wastewater ) 是由 关文辉 于 2020-05-19 设计创作，主要内容包括：本发明公开了一种应用于放射性工业废水的处理控制方法,属于废水处理技术领域,一种应用于放射性工业废水的处理控制方法,包括通过粘土矿物、粉煤灰、金属氧化物磨粉得到混合预料,在加工改性的纤维与混合预料搅拌混合,制得放射性元素吸附剂,有利于扩大吸附剂的吸附面积以及吸附性能,最后将放射性元素吸附剂浸渍于纳米铁磁溶液中,实现放射性元素吸附剂的附磁,得到附磁后的放射性元素吸附剂,附磁后,不仅能够对放射性元素进行吸附还能够对其它金属离子进行有效吸附,提高吸附剂的吸附性能,同时,附磁后的放射性元素吸附剂也易于稳定地填充于带有电磁元件的吸附器内,在使用完成后,电磁元件断电后,即可实现对吸附剂的回收。(The invention discloses a treatment control method applied to radioactive industrial wastewater, belonging to the technical field of wastewater treatment, and the treatment control method applied to the radioactive industrial wastewater comprises the steps of obtaining a mixed prediction by grinding clay minerals, fly ash and metal oxides, stirring and mixing the processed and modified fibers with the mixed prediction to prepare a radioactive element adsorbent, being beneficial to expanding the adsorption area and the adsorption performance of the adsorbent, finally soaking the radioactive element adsorbent in a nano ferromagnetic solution to realize the magnetization of the radioactive element adsorbent to obtain the magnetized radioactive element adsorbent, adsorbing radioactive elements and effectively adsorbing other metal ions to improve the adsorption performance of the adsorbent, and simultaneously easily and stably filling the magnetized radioactive element adsorbent in an adsorber with an electromagnetic element, after the use is finished, the electromagnetic element is powered off, and then the recovery of the adsorbent can be realized.)

1. A treatment control method applied to radioactive industrial wastewater is characterized by comprising the following steps: the specific treatment control method comprises the following steps:

s1, selecting clay minerals, fly ash, metal oxides, fibers and industrial water as raw materials for preparing an adsorbent for later use;

s2, placing the clay mineral, the fly ash and the metal oxide into a grinder to be fully crushed, sieving to obtain mixed powder with the particle size smaller than 20um, and adding industrial water to be fully mixed and stirred to obtain a mixed prediction;

s3, soaking the fiber in an acid solution, and reacting to obtain a modified fiber so as to realize efficient adsorption of multiple heavy metal ions;

s4, stirring and mixing the modified fiber obtained in the S3 and the mixed material obtained in the S2, granulating and drying to obtain a radioactive element adsorbent, and soaking the radioactive element adsorbent in a nano ferromagnetic solution to realize the magnetization of the radioactive element adsorbent and obtain the magnetized radioactive element adsorbent;

and S5, placing the metal element adsorbent subjected to magnetism attachment obtained in the S4 into an adsorber, installing an electromagnetic element in the adsorber, adsorbing and fixing the metal element adsorbent subjected to magnetism attachment by the electromagnetic element, and introducing the industrial wastewater to be treated into the adsorber for adsorption and filtration so as to effectively remove radioactive elements in the wastewater.

2. The method for controlling the treatment of radioactive industrial wastewater according to claim 1, wherein: the clay mineral in the S1 includes but is not limited to one or more of zeolite, kaolin, sepiolite and vermiculite, and the metal oxide includes but is not limited to one or more of nano-silica and activated alumina.

3. The method for controlling the treatment of radioactive industrial wastewater according to claim 1, wherein: the acidic solution in S3 includes, but is not limited to, one or more of phosphoric acid, amino acid, and methyl ester acid.

4. The method for controlling the treatment of radioactive industrial wastewater according to claim 1, wherein: the adsorber includes filtering ponds (1) and support column (2) of fixed mounting in filtering ponds (1), support column (2) are close to the upper end on the lateral wall all around fixedly connected with adsorption tanks (3), the dirty mechanism of top fixedly connected with of support column (2) advances, advance dirty mechanism respectively with the top fixed connection of a plurality of adsorption tanks (3), the radioactive element adsorbent that attaches after the magnetism is filled in the inside of every adsorption tank (3), and the bottom of every adsorption tank (3) is equipped with the filtration pore.

5. The method for controlling the treatment of the radioactive industrial wastewater according to claim 4, wherein a rotating door (301) is rotatably installed on the outer wall of one end of each adsorption tank (3), an electromagnet (4) is installed on the inner wall of each adsorption tank (3), and a liquid distributor (5) communicated with a sewage inlet mechanism is fixedly installed at the top end of each adsorption tank (3).

6. The method for controlling the treatment of radioactive industrial wastewater according to claim 5, wherein: advance dirty mechanism and include shunt tubes (6) through bracing piece (8) fixed connection on support column (2), the top fixedly connected with of shunt tubes (6) advances dirty pipe (7), equal fixedly connected with and honeycomb duct (9) that liquid distributor (5) position corresponds on the lateral wall all around of shunt tubes (6), the top portion of locating liquid distributor (5) is inserted to the bottom of honeycomb duct (9).

7. The method for controlling the treatment of radioactive industrial wastewater according to claim 1, wherein: the utility model discloses a filtration pond, including filtering pond (1), support column (2), filtration membrane (10), filtration pond (1) is close to the inside of upper end and inlays to establish and install filtration membrane (10), on filtration membrane (10) was located to support column (2) cover, the interior bottom fixedly connected with fixed column of filtering pond (1), the bottom of support column (2) runs through filtration membrane (10) and the fastening is inserted and is located in the fixed column.

8. The method for controlling the treatment of radioactive industrial wastewater according to claim 6, wherein: the sewage treatment device is characterized in that a drain pipe is fixedly mounted on one end side wall of the filtering tank (1), a circulating pipe (11) is fixedly connected onto the other end side wall of the filtering tank (1), a circulating pump mounted on the circulating pipe (11) is arranged on the other side of the filtering tank (1), and the upper end of the circulating pipe (11) is connected onto the inner wall of the sewage inlet pipe (7).

9. The method for controlling the treatment of radioactive industrial wastewater according to claim 7, wherein: the utility model discloses a filter bed, including filtering pond (1), fixed mounting has a plurality of filter frames that correspond with adsorption tank (3) position on the inside lateral wall all around, every the filter frame intussuseption is filled with cobble layer (12), filtration membrane (10) are placed on a plurality of cobble layers (12).

Technical Field

The invention relates to the technical field of wastewater treatment, in particular to a treatment control method applied to radioactive industrial wastewater.

Background

A large amount of radioactive elements are mixed in wastewater discharged by some nuclear power stations, the nuclear power discharged wastewater contains high-radioactivity isotope nuclear elements such as strontium, cesium, technetium, uranium, thorium and the like, the radioactive wastewater usually contains nuclide ions such as silver, cobalt, strontium and the like, and the removal of the nuclide ions is significant for reducing the radioactivity level of the wastewater. Meanwhile, the high-radioactivity isotope nuclear elements have great application value in the fields of medical treatment and the like, and if the high-radioactivity isotope nuclear elements are not treated, a great amount of valuable substances are lost without any reason when the high-radioactivity isotope nuclear elements are discharged.

The prior method for treating nuclear radioactive industrial wastewater generally adopts methods such as flocculation precipitation, evaporation, ion exchange, biological treatment, membrane technology and the like, and the treatment methods have the defects of low treatment efficiency, high treatment cost, complicated subsequent treatment, secondary pollution and the like.

Adsorption is an effective, convenient and stable treatment method and is widely applied to the treatment of wastewater containing radioactive elements. The adsorption method in the prior art is a main method for treating radioactive wastewater, the development and selection of an adsorbent are one of the key research points for removing the nuclear pollution in the radioactive wastewater by the adsorption method, and the performance of the adsorbent determines the adsorption treatment effect. Meanwhile, the inorganic adsorbent has the advantages of low raw material cost, simple manufacturing process, few byproducts and the like, and is very suitable for treating the radioactive metal ion polluted water body. The existing adsorbent is porous single products such as zeolite and active carbon, but the existing adsorbent is single, the adsorption pores of the existing adsorbent are pores of the product, and the adsorption area is difficult to change, so that the adsorption performance of the existing adsorbent is still to be improved.

Therefore, the adsorption method applied to the radioactive industrial wastewater treatment control method is adopted to meet the urgent requirements of radioactive wastewater treatment in the prior art.

Disclosure of Invention

1. Technical problem to be solved

In view of the problems in the prior art, the invention aims to provide a treatment control method applied to radioactive industrial wastewater.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A treatment control method applied to radioactive industrial wastewater is characterized by comprising the following steps: the specific treatment control method comprises the following steps:

s1, selecting clay minerals, fly ash, metal oxides, fibers and industrial water as raw materials for preparing an adsorbent for later use;

s2, placing the clay mineral, the fly ash and the metal oxide into a grinder to be fully crushed, sieving to obtain mixed powder with the particle size smaller than 20um, and adding industrial water to be fully mixed and stirred to obtain a mixed prediction;

s3, soaking the fiber in an acid solution, and reacting to obtain a modified fiber so as to realize efficient adsorption of multiple heavy metal ions;

s4, stirring and mixing the modified fiber obtained in the S3 and the mixed material obtained in the S2, granulating and drying to obtain a radioactive element adsorbent, and soaking the radioactive element adsorbent in a nano ferromagnetic solution to realize the magnetization of the radioactive element adsorbent and obtain the magnetized radioactive element adsorbent;

and S5, placing the metal element adsorbent subjected to magnetism attachment obtained in the S4 into an adsorber, installing an electromagnetic element in the adsorber, adsorbing and fixing the metal element adsorbent subjected to magnetism attachment by the electromagnetic element, and introducing the industrial wastewater to be treated into the adsorber for adsorption and filtration so as to effectively remove radioactive elements in the wastewater.

Further, the clay mineral in S1 includes, but is not limited to, one or more of zeolite, kaolin, sepiolite, and vermiculite, and the metal oxide includes, but is not limited to, one or more of nano-silica and activated alumina, the clay mineral has the characteristics of adsorbing certain cations and anions and maintaining in an exchange state, for example, zeolite, kaolin, sepiolite, vermiculite, etc. all have adsorption pores, and effectively adsorb GR, CS, etc., and the clay mineral is pillared by the metal oxide, which is beneficial to increasing the surface area and the size of the void, and is easy to improve the adsorption performance, while the capillary channel surface of nano-silica and activated alumina has higher activity, further enhancing the adsorption performance.

Further, the acidic solution in S3 includes, but is not limited to, one or more of phosphoric acid, amino acid, methyl ester acid, and the catalytic effect of the acid on the crosslinking and dehydration reaction of the fiber introduces new chemically active groups to improve the adsorption performance of the fiber.

Further, the adsorber includes filtering ponds and fixed mounting's support column in filtering ponds, the support column is close to the upper end fixedly connected with adsorption tanks on the lateral wall all around, the top fixedly connected with of support column advances dirty mechanism, advance dirty mechanism respectively with the top fixed connection of a plurality of adsorption tanks, the radioactive element adsorbent that attaches after the magnetism fills in the inside of every adsorption tank, and the bottom of every adsorption tank is equipped with the filtration pore, through advancing the leading-in industrial waste water of dirty mechanism to along with the leading-in to adsorption tanks of industrial waste water reposition of redundant personnel, the radioactive element adsorbent is flowed through to the industrial waste water of leading-in to adsorption tanks department, adsorbs the multiple radioactive metal element in the waste water through the adsorbent, and the adsorbent is magnetic by the way simultaneously, still effectively adsorbs some magnetic metals in the waste water.

Further, every rotate on the one end outer wall of adsorption tank and install the turnstile, install the electro-magnet on the adsorption tank inner wall, and the top fixed mounting of every adsorption tank has the liquid distributor that is linked together with the dirty mechanism that advances, and liquid distributor easily carries out dispersion treatment to waste water to effectively make the abundant radioactive element adsorbent department of flowing through of waste water.

Further, advance dirty mechanism and include the shunt tubes through bracing piece fixed connection on the support column, the top fixedly connected with of shunt tubes advances dirty pipe, equal fixedly connected with honeycomb duct that corresponds with liquid distributor position on the lateral wall all around of shunt tubes, the top portion of locating liquid distributor is inserted to the bottom of honeycomb duct.

Further, the filtering pond is close to the inside of upper end and inlays to establish and install filtration membrane, the support column cover is located on filtration membrane, the interior bottom fixedly connected with fixed column of filtering pond, the bottom of support column runs through filtration membrane and fastening and inserts and locate in the fixed column, and waste water after handling through the adsorption tank flows through the filtration membrane, further improves the waste water treatment effect.

Further, fixed mounting has the drain pipe on the one end lateral wall of filtering ponds, the intraductal installation valve of drain, fixedly connected with circulating pipe on the other end lateral wall of filtering ponds, the opposite side of filtering ponds is equipped with the circulating pump of installing on the circulating pipe, the upper end of circulating pipe is connected on the inner wall of advancing dirty pipe, adds the circulating pipe, can be with waste water in the filtering ponds leading-in again to advancing dirty intraductal, realize the absorption filtration processing many times of waste water.

Further, fixed mounting has a plurality of filtration frames that correspond with the adsorption tank position on the inside lateral wall all around of filtering ponds, every it is filled with the cobble layer to filter the frame intussuseption, filtration membrane places on a plurality of cobble layers, and the cobble layer that fills plays the bearing effect to filtration membrane on the one hand, and the waste water that flows down on the other hand filters through the cobble layer once more, effectively improves purifying effect.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) according to the scheme, the mixed prediction is obtained through clay minerals, fly ash and metal oxide powder grinding, the modified fibers are stirred and mixed with the mixed prediction to prepare the radioactive element adsorbent, the adsorption area and the adsorption performance of the adsorbent are favorably enlarged, and finally, the radioactive element adsorbent is immersed in a nano ferromagnetic solution to realize the magnetism adsorption of the radioactive element adsorbent, so that the radioactive element adsorbent after the magnetism adsorption is obtained, and after the magnetism adsorption, the radioactive element adsorbent not only can adsorb radioactive elements but also can effectively adsorb other metal ions, and the adsorption performance of the adsorbent is improved.

(2) The clay mineral comprises but is not limited to one or more of zeolite, kaolin, sepiolite and vermiculite, the metal oxide comprises but is not limited to one or more of nano-silica and activated alumina, the clay mineral has the characteristics of adsorbing certain cations and anions and keeping in an exchange state, for example, the zeolite, the kaolin, the sepiolite and the vermiculite have adsorption pores, and the clay mineral is pillared by the metal oxide, so that the surface area and the cavity size of the clay mineral are increased, the adsorption performance is easy to improve, and simultaneously, the capillary channel surfaces of the nano-silica and the activated alumina have higher activity, so that the characteristics of large surface area and high porosity of the adsorbent are realized, and the adsorption performance of the adsorbent is further enhanced.

(3) The acidic solution comprises one or more of phosphoric acid, amino acid and methyl ester acid, the acid has a catalytic effect on the cross-linking and dehydration reaction of the fiber, and a new chemical active group is introduced to improve the adsorption performance of the fiber.

(4) Rotate on the one end outer wall of every adsorption tank and install the turnstile, install the electro-magnet on the adsorption tank inner wall, and the top fixed mounting of every adsorption tank has the liquid distributor that is linked together with the dirty mechanism that advances, liquid distributor easily carries out dispersion treatment to waste water, thereby effectively make waste water fully flow through radioactive element adsorbent department, cooperate with the radioactive element adsorbent that attaches after the magnetism through the electro-magnet, after the electro-magnet starts, thereby be convenient for technical staff will attach the radioactive element adsorbent after the magnetism and lay inside, so that fix a position the absorption to the radioactive element adsorbent, after the use is accomplished, open the turnstile, the electro-magnet cuts off the power supply, so that dismantle the radioactive element adsorbent from the inside, thereby retrieve the radioactive element in the adsorbent.

(5) Through addding filtration membrane and cobblestone layer, further effectively improve waste water filtration purification effect, and add the circulating pipe of establishing and advancing dirty pipe and being linked together in the filtering ponds bottom, can be with leading-in again to advancing dirty intraductal with the waste water in the filtering ponds, realize the absorption filtration treatment many times of waste water.

Drawings

FIG. 1 is a process flow diagram of the present invention;

FIG. 2 is a perspective view of an adsorber of the present invention;

FIG. 3 is a cross-sectional view of the interior of the adsorber of the present invention;

FIG. 4 is a perspective view of the combination of the support column and the adsorption box of the present invention;

fig. 5 is a perspective view of the junction of the filtering ponds and the pebble bed of the present invention.

The reference numbers in the figures illustrate:

1 filtering pond, 2 support columns, 3 adsorption tanks, 301 revolving door, 4 electromagnets, 5 liquid distributors, 6 shunt pipes, 7 sewage inlet pipes, 8 support rods, 9 diversion pipes, 10 filtering membranes, 11 circulating pipes and 12 cobble layers.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.