JPH033737B2 - - Google Patents

Description

[Detailed description of the invention]

[Industrial Application Field] The present invention relates to a method for simultaneously processing special steel dust and sludge and steelmaking slag by actively utilizing the sensible heat of high-temperature slag discharged from a steelmaking furnace. It is. [Prior art] Special steel dust and sludge generated during the manufacture of special steel are mainly composed of iron oxide, but only a few percent of
Although it contains Ni, it is of low quality, and it also contains Cr, Pb,
Contains harmful ingredients such as Zn, Cu, Cd, S, F, etc.
It cannot be used as a Ni raw material, and furthermore, the special steel dust and sludge cannot be disposed of as they are because they elute heavy metal ions, and are disposed of as industrial waste at great expense. On the other hand, high-temperature steelmaking slag (hereinafter referred to as slag) discharged from various steelmaking furnaces such as blast furnaces, converters, electric furnaces, and electric furnaces for ferroalloys generated in the steel industry remains at a high temperature. At present, this enormous amount of heat energy is being wasted and unused. [Problems to be solved by the invention] Therefore, it is considered necessary to actively utilize the unused thermal energy mentioned above to treat dust and sludge. There is a method for recovering valuable metals from steelmaking dust and sludge using molten slag, which is described in Japanese Patent Application No. 111306/1986, which I previously researched and filed. Another method is to make pellets and place them in the bottom of the slag pot of a converter or electric furnace in advance, and then pour the high-temperature slag over the top. According to this method, briquettes or pellets can be made in response to changes in steelmaking operations. It has been confirmed that the method has disadvantages in that it is not possible to control the appropriate charge amount and that unreacted dust, sludge briquettes, or pellets sometimes remain. In addition, since steelmaking slag is discharged in a high-temperature molten state and is rich in CaO, efforts are being made to recycle its disposal.
Steelmaking slag is mainly composed of free lime in steelmaking slag,
Due to the expansion collapse phenomenon caused by 2CaO, SiO _2, etc.
Except for use in cement raw materials, fertilizers, etc., it cannot be used as a civil construction material, so the entire amount generated was not utilized, and most of it was disposed of in landfills. The present invention was made in view of the above circumstances, and it completely suppresses the reaction in the slag to more completely recover valuable metals contained in special steel dust and sludge, and eliminate pollution from harmful components. At the same time, the aim is to stabilize steelmaking slag and to make it more widely available as a resource. [Means for Solving the Problems] The present invention, which meets the above objectives, provides special steel dust and sludge, and an amount of a reducing agent and a chlorinating agent necessary to react with the metal compounds in the special steel dust and sludge. and a modifier in the amount necessary for modifying the steelmaking slag, and then agglomerates into a predetermined size; and drying and preheating the agglomerates obtained in the first step. The dried agglomerates obtained in the second step are poured into high-temperature molten steelmaking slag, and a chloride-reduction reaction is caused by the sensible heat of the high-temperature molten steelmaking slag. The third step involves converting the valuable metals into metals and reforming the steelmaking slag by causing a molten slag reaction, and cooling and solidifying the material in the slag ladle, then crushing it, and then converting it into metals using normal beneficiation methods. The process consists of a fourth step of separating Ni and Fe, which have turned into molten slag, from steelmaking slag, which has turned into molten slag. The modifiers used in the first step include components that eliminate free CaO and MgO, which are contained in steelmaking slag and are the main cause of expansion and collapse phenomena, as well as unstable minerals 2CaO, SiO ₂ , 3CaO, 2SiO ₂ is a stable compound CaO/SiO ₂ that can also be used as a civil construction material.
2CaO・Al ₂ O ₃・SiO ₂ , 2CaO・MgO・2SiO ₂ ,
It is effective to have a low melting point that contains the necessary components to convert into 2CaO・Fe ₂ O ₃ , 4CaO・Al ₂ O ₃・Fe ₂ O ₃ (the above reaction is called the molten slag reaction). For example, silicate minerals whose main components are SiO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , rocks or their weathered products, sandstone, silica sand, foundry waste sand, volcanic ash, coal ash, red mud, copper. , zinc, acidic cupora slag, etc. are used. The amount used varies slightly depending on the basicity of the steelmaking slag, but is usually about 5 to 15% by weight of the amount of slag. In addition, the reducing agent used in the first step includes carbonaceous reducing agents such as coke or wood flour,
Cast iron powder, aluminum powder, ferrosilicon, etc. are also included, but it is usually preferable to use an inexpensive carbonaceous reducing agent such as coke or wood flour. Further, when a carbonaceous reducing agent is used, it is preferable that the amount of carbon added is 1 to 5 times the theoretical amount required for Ni reduction, and the particle size is 5 mm or less. The above chlorinating agent is usually inexpensive CaCl ₂
However, when CaCl ₂ or NaCl is used, the amount of the chlorinating agent added is preferably 0.5 to 1.5 times the theoretical amount required to chlorinate Ni. Note that agglomerating into a predetermined size refers to forming into briquettes or pellets, but is not limited to this. [Operation] Next, the processing procedure and operation of the method for simultaneously processing special steel dust, sludge, and steelmaking slag according to the present invention will be described in detail. In the first step, a predetermined amount of reducing agent, chlorinating agent, and modifier are added to dust and sludge, kneaded, and agglomerated. In the second step, the agglomerated product is dried and preheated. This is because when excessive moisture is present, hydrolysis as shown by NiCl ₂ +H ₂ O→NiO+2HCl or FeCl ₂ +H ₂ O→FeO+2HCl occurs, and the chlorination reaction of Ni and Fe is inhibited. In addition, sufficient drying and preheating not only prevents heat loss of the sensible heat of the slag due to moisture, but also prevents the agglomerated material added to the slag from bursting into powder. The third step is a step in which the agglomerated material from the second step is introduced into the hot slag, resulting in a turbulent flow of the material falling into the slag pot.
The agglomerates are immersed in the slag by high-pressure gas blowing or mechanical agitation turbulence, and the sensible heat promotes the chloride-reduction reaction of Ni and Fe and causes the slag formation reaction to produce steel. This is a step of reforming slag, and since the slag formation reaction has been described above, the chloride-reduction reaction will be explained. The Ni and Fe compounds first become NiCl ₂ and FeCl ₂ and gasify, and then precipitate as reduced metals on the surface of the reducing agent. That is, the precipitation mechanism is C and
Because Fe decomposes H ₂ O generated in the chlorination reaction (NiO + 2HCl → NiCl ₂ + H ₂ O) and generates H ₂ ,
It is thought that NiCl ₂ is reduced on the surface of the reducing agent where the H ₂ partial pressure increases and metal Ni is precipitated. In this case, if cast iron powder is used as the reducing agent,
Even if carbonaceous reduced particles with low Ni precipitation and weak magnetism are present, the cast iron powder is ferromagnetic, so it is easily magnetized by the fine particle magnetic pole effect, and the precipitated Ni is recovered by magnetic beneficiation. In addition, the above-mentioned slag formation reaction also requires heat, and the amount of modifier is determined depending on the amount of slag, so a large amount of dust and sludge cannot be mixed into the agglomerated product. The amount of agglomerates must be adjusted to the sensible heat of the slag, and the amount of agglomerates is usually 30% of the amount of slag.
It is as follows. Therefore, when trying to process a large amount of dust and sludge, heat is required, so it is necessary to heat the agglomerates by using an auxiliary electrode or auxiliary burner, or to heat the agglomerates to be thrown into the slag. It is necessary to preheat sufficiently. [Example] Next, a case in which the method of the present invention is applied to ferroalloy slag, which is an example of high-temperature molten steelmaking slag, will be described in detail with reference to the attached drawings. Here, FIG. 1 is a process explanatory diagram of a method for simultaneously treating special steel dust, sludge, and steelmaking slag according to an embodiment of the method of the present invention. The metal and molten slag tapped from the electric alloy furnace 1 are separated by specific gravity in the metal ladle 2, and only the molten slag 4 overflows and falls into the next ladle 3 and is stored. On the other hand, the dust, sludge, and the required amount of reducing agent, chlorinating agent, and modifier are kneaded, and if necessary, a binder for making the dough is added to the dough making machine 8.
The briquettes 5 are prepared by the drying and preheating device 7, and the dry and preheated briquettes 5 are prepared in the feeder 6. After that, when the molten slag 4 falls into the ladle 3, the dry and preheated briquettes 5 are simultaneously dropped from the feeder 6, and are mixed well in the ladle 3, so that the sensible heat of the molten slag is sufficiently transferred to the briquettes 5. , promotes the chloride-reduction reaction of Ni and Fe in the briquette 5, and also promotes the modification of steelmaking slag by the modifier. Here, when the temperature of briquette 5 reaches about 800℃ or higher,
A chloride-reduction reaction takes place and mainly produces metal Ni, but since a portion of Fe is also metalized by the same reaction, an Fe-Ni alloy is actually produced. In this case, it is preferable to sufficiently bubble the slag with a high-pressure lance pipe (not shown) to uniformly promote the reaction. In this process, the above-mentioned chloride-reduction reaction occurs, and the steelmaking slag is reformed, and the volatile components contained in the dust and sludge are volatilized. Next, the treated slag 9 is discharged or cooled and solidified in a slag pot, and then sent to a beneficiation step 10 where it is crushed, magnetically beneficiation, and gravity beneficiation to produce reduced metal grains mainly composed of Ni and reformed. The resulting steelmaking slag is separated and recovered. [Example] Next, an experimental example conducted in order to confirm the effects of the present invention will be described. Note that the same components as those in the above embodiment are given the same numbers and their explanations will be omitted. Approximately 600 kg of molten slag 12 made by remelting steelmaking slag in an Elou type electric furnace 11 flows into an iron slag ladle 13 as shown in FIG. 2, and then a lance pipe 14 is inserted into the slag 12. Then, remove the slag 12 with high pressure air.
While bubbling, 15 parts by weight of coke powder, 10 parts by weight of cast iron powder, and 5 parts by weight of calcium chloride, which is an example of a modifier, are divided into 100 parts by weight of stainless steel dust and crushed appropriately. After that, 70 kg of the briquettes, which had been compacted and sufficiently dried and preheated, were poured into the slag at a rate of 7 kg per minute, and left to stand for about 3 hours to solidify by tumbling. Cooled to room temperature. Thereafter, the solidified treated steelmaking slag 15 was crushed and subjected to magnetic beneficiation in a magnetic beneficiation step 16, and the results were as shown in Table 1. At this time, the temperature of the slag when tapped from the electric furnace was 1600℃.
The temperature of the slag at the end of briquetting is approximately 1400℃.
It was hot.

〔Effect of the invention〕

The present invention is configured as described above, and since the reaction in the slag is completely carried out, it is possible to recover valuable metals and treat harmful components contained in special steel dust and sludge. It turned out to be easy to do. In particular, regarding the recovery of valuable metals, it has become possible to selectively concentrate and recover Ni contained in special steel dust and sludge through a chloride-reduction reaction. At the same time, steelmaking slag is modified and stabilized, making it possible to use steelmaking slag more widely as a resource. In this way, the present invention makes it possible to effectively utilize the sensible heat of the slag, which was previously wasted, and to eliminate pollution from dust and sludge, which have become a serious problem due to pollution, while recovering Ni and Fe. It is of great industrial significance that it can also be used to modify steelmaking slag.

[Brief explanation of drawings]

FIG. 1 is a process diagram of a method for simultaneously treating special steel dust, sludge, and steelmaking slag according to an embodiment of the present invention, and FIG. 2 is a process diagram for simultaneously treating special steel dust, sludge, and steelmaking slag according to a method of the present invention It is a process diagram of an experiment conducted to confirm the effect of the simultaneous processing method. Explanation of symbols, 1...Electric furnace, 2...Metal ladle, 3...Slag ladle, 4...Smelt slag, 5...Dried briquette, 6...Briquette feeder, 7...
Briquette drying preheating device, 8...Pulling machine, 9...
Steelmaking slag after treatment, 10...Ore beneficiation process, 11...
...Electric furnace, 12...Slag, 13...Slag pot, 14
... Lance-shaped pipe, 15 ... Steelmaking slag after treatment, 16 ... Ore beneficiation process.

Claims (1)

[Claims] 1. A method for simultaneously processing special steel dust, sludge, and steelmaking slag, comprising the following steps: 1st step: special steel dust, sludge, and metal compounds in the special steel dust, sludge, etc. After kneading the reducing agent and chlorinating agent in the amount necessary to react with the steelmaking slag and the modifier in the amount necessary to modify the steelmaking slag, the mixture is agglomerated into a predetermined size. Second step: Dry and preheat the agglomerated product obtained in the first step. Third step: The dried agglomerates obtained in the second step are put into high-temperature molten steelmaking slag, and a chloride-reduction reaction is caused by the sensible heat of the high-temperature molten steelmaking slag, mainly containing valuable Ni and Fe. This process modifies steelmaking slag by metallizing the metal and causing a molten slag reaction. 4th step: The material in the slag pot is cooled and solidified, then crushed and metalized using normal ore beneficiation means.
Separate Fe and steelmaking slag that has become molten slag. 2. Modifiers for steelmaking slag used in the first step include silicate minerals, rocks or their weathered products, sandstone, silica sand, foundry waste sand, volcanic ash, coal ash, red mud, copper, zinc, and acid cupora. A method for simultaneously processing special steel dust, sludge, and steelmaking slag according to claim 1, which contains at least one type of slag. 3. A method for simultaneously treating special steel dust, sludge, and steelmaking slag according to claim 1 or 2, wherein the reducing agent used in the first step is a carbonaceous reducing agent such as coke or wood flour. 4. A method for simultaneously treating special steel dust, sludge, and steelmaking slag according to claim 1 or 2, wherein the reducing agent used in the first step is cast iron powder. 5. In the third step, when the dry agglomerates and high-temperature molten steel slag are introduced into the slag pot, the claims 1 and 2 include adding these at the same time.
The special steel dust according to item 3 or 4,
A method for simultaneously processing sludge and steelmaking slag.