KR20000042150A - Method for collecting valuable metal from industrial waste using plasma - Google Patents

Abstract

PURPOSE: A method for collecting valuable metal from industrial waste using plasma is provided to volatilize zinc vapor in an airtight furnace in order to increase zinc collecting ratio and to easily reduce oxidized steel and oxidized zinc by using plasma as a heat source. CONSTITUTION: Nitrogen gas as plasma gas is supplied to a plasma gas supply passage(31). The plasma gas passage is formed in the middle of a cathode electrode bar(3). Nitrogen gas is plasmatic to generate arc at an electric point of contact by supplying power to the cathode bar and an anode(4). Then, the dust in the furnace(2) is molten. When industrial waste is charged into the furnace through a raw material charging apparatus(1), first oxidized zinc is reduced and volatilized by directly heating the waste with heat of plasma and zinc metal is collected within a temperature of 430 to 500°C in a zinc collector(5). Then, the waste is molten in the furnace in a temperature of 1200 to 1400°C and molten metal steel is collected through an exit hole(22) after being separated from slag.

Description

Recovery of valuable metals from industrial waste using plasma

The present invention relates to a method for recovering valuable metals by treating dust generated as a by-product from various electric furnace operations using plasma, and more particularly, by dissolving industrial wastes using plasma, such as metal iron and metal zinc. It is about a method of recovering valuable metals.

In general, various dusts generated during the operation of electric furnaces contain heavy metals that are harmful to the human body and are solidified with cement to be landfilled or reprocessed in a melting furnace to recover valuable metals.

Techniques for reprocessing such dusts include techniques for recovering valuable metals directly from dust, such as Japanese Patent Laid-Open Nos. 97-263844, 97-241773, 96-214546, and the like.

In Japanese Patent Application Laid-Open No. 97-263844, industrial wastes containing trace amounts of valuable metals are combusted in an incinerator so that the proportion of valuable metals is reusable, and the incinerator, zinc slag, and powder coke are mixed and sintered in a sintering machine to coke. The mixture is preheated, and then melted using a Stocker electrothermal distillation furnace to obtain distilled zinc.

In addition, Japanese Patent Application Laid-Open No. 97-241773 discloses a technique configured to recover zinc in dust by roasting and volatilizing zinc-containing dust, followed by wet treatment with an aqueous sulfuric acid solution.

However, this process has a problem of having a very complicated process including an eb treatment and a post treatment process, and most of the processes are configured to be exposed to the atmosphere, making it inconvenient to treat valuable metals such as volatilized zinc.

In addition, there is a limit to the object to be treated because it is exposed, and it is difficult to improve the recovery of valuable metals by supplying sufficient heat, and in the case of wet treatment, sulfuric acid solution must be treated in a separate process. It was required to solve the secondary pollution problem caused by the light.

In addition, when industrial wastes are secondary dusts generated in electric furnaces, they are recovered in the first way by recovering valuable metals, and dust generated by regenerating is almost impossible to process in exposed resistance furnaces. It is true.

The present inventors have studied to solve the above problems of the prior art, and as a result, the plasma used as the heat source is excited by the specific energy and is present in the state separated from the atom, thus distinguishing it from gas, liquid, and solid. When this plasma state is reached, it retains very high energy in latent heat, but it is placed in an unstable state, and it is ionized locally by removing the system that maintains the unstable state or by leaving it. Although it is in an electrically neutral state, the focus of the plasma is estimated to be about 10,000 to 20,000 degrees in the center and an external temperature of about 3000 to 4,000 degrees.

When argon, which is an inert gas, is used as a plasma gas, a high temperature can be obtained as a clean heat source, and when a gas such as hydrogen, nitrogen, and carbon monoxide is used as a plasma gas, compounds that are difficult to manufacture by a general method can be synthesized.

In addition, metallurgy is not widely used due to the cost increase due to the large use of electricity and gas, but the possibility of plasma use in the smelting process has been steadily reviewed and some practically used, mainly in northern Europe, where electricity prices are low.

At this time, the plasma is used as a clean heat source, and since heat transfer starts from the bottom of the melt, compared to other heat sources that must transfer heat from the surface of the melt to the inside, a relatively high thermal efficiency can be expected and the stirring effect of the melt is excellent and the heat distribution is even. Has an advantage.

The present invention has been made in order to solve the problems of the prior art described above, to improve the zinc recovery rate to reduce the zinc oxide and zinc oxide by volatilizing zinc vapor in a closed furnace to give a sufficient amount of heat to the dust using a plasma as a heat source It is an object of the present invention to provide a method for recovering valuable metals from industrial waste using plasma that facilitates the use of the same.

1 is a view schematically showing an apparatus for practicing the present invention,

2 is a view showing the recovery rate of metal iron according to the elevated temperature of the furnace in Example 1 of the present invention,

3 is a diagram showing a slag generation rate that is different from the furnace temperature rise temperature in Example 1 of the present invention;

4 is a view showing a metal zinc recovery rate according to the furnace temperature increase temperature in the present invention,

5 is a view showing the recovery rate of metal iron according to the elevated temperature of the furnace in Example 2 of the present invention,

FIG. 6 is a diagram showing slag generation rate according to the elevated temperature of the furnace in Example 2 of the present invention. FIG.

<Explanation of symbols for main parts of drawing>

1: raw material charging device 2: furnace 3: cathode electrode 4: anode

5: zinc collecting device 6: power supply device 7: exhaust gas treatment device

21: zinc steam outlet 22: hot water outlet 31: plasma gas supply passage

The method for recovering the valuable metals from the industrial waste of the present invention for achieving the above object, the temperature of the furnace to 1200 ~ 1400 ℃ by the heat generated by applying the power between the cathode and anode of the plasma generation furnace to plasma the gas It heats up and is a structure characterized by dissolving industrial waste.

In addition, in the present invention, the zinc volatilized by heat applied to industrial waste such as dust generated in an electric furnace or secondary dust generated during such dust treatment is recovered through a zinc collecting device at 430 to 500 ° C.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments.

First, an apparatus for recovering valuable metals from industrial waste such as dust for carrying out the present invention will be described with reference to FIG. 1.

The anode electrode 4 is provided at the bottom of the furnace 2 for generating plasma, and the cathode electrode rod 3 on which the plasma gas supply passage 31 is formed extends vertically through the center of the furnace 2. The furnace 2 is provided with a raw material charging device 1 for injecting industrial waste, such as an electric furnace primary dust or an electric furnace secondary dust, into the furnace 2, and the upper portion of the furnace 2 A zinc vapor outlet 21 for recovering volatilized zinc is provided at the center of the side wall, and a hot water outlet 22 for separating and recovering the obtained iron and slag is provided at the bottom of the furnace side wall.

In addition, a zinc collecting device 5 for recovering zinc from the zinc vapor flowing out through the outlet 21 adjacent to the furnace 2 is provided, from which the exhaust gas treatment device 7 and the stack 8 are downstream. This is installed.

The cathode electrode 3 and the anode 4 provided in the furnace 2 are configured to supply power from the power supply device 6 to generate plasma between the anode and the cathode rods.

Referring to the process of recovering the metal iron and zinc from industrial waste by using the plasma generating apparatus of the above configuration, nitrogen is plasma to the plasma gas supply passage 31, such as nitrogen gas formed in the center of the cathode electrode (3) While supplying gas, power is supplied to the cathode rod 3 and the anode 4 to generate an arc at the electrical contact to plasma the nitrogen gas to dissolve the dust present in the furnace. When charged into the furnace (2) through the heat directly to the heat of the plasma to reduce the zinc oxide first volatilized and the zinc collecting device 5 to recover the metal zinc in the range of 430 ~ 500 ℃.

Subsequently, the temperature of the furnace 2 is adjusted to a temperature of 1200 to 1400 ° C. to increase the temperature to dissolve the industrial wastes, and to separate the molten metal iron and slag collected at the bottom and tap the water through the hot water outlet 22 to supply the metal iron. Recover.

Hereinafter, the present invention will be described in more detail with reference to Examples.

Example 1

The dust and coke generated in the electric furnace as a raw material were mixed with 17% of the powdered coke and mixed evenly so that the loading amount was 350 kg, and 70 kg of electrolytic iron was charged together to generate plasma smoothly. Metal waste and zinc were recovered by dissolving the charged industrial wastes at a reduction temperature of the electric furnace dust, which is industrial wastes, in the range of 1100 to 1450 ° C, respectively, in the range of 1100 ° C, 1200 ° C, 1300 ° C, 1400 ° C, and 1450 ° C. The recovery amount of the tap iron and slag was measured to measure the recovery rate of metal iron by temperature, and is shown in FIG. 2.

The recovery rate of metal iron was calculated by using the chemical analysis table as shown in Table 1, and then recovering the recoverable amount in 350 kg of the input material, and then calculated by the ratio between the calculated prediction value and the actual recovery amount.

Since iron contained in dust is mainly composed of Fe ₂ O ₃ , pure iron is composed of _three oxygen and two iron atoms, so in terms of weight ratio, about 70% of the amount of Fe ₂ O ₃ can be recovered as metallic iron. The possible amount can be obtained as follows.

Theoretical recoverable amount = (loading amount-coke amount) X Fe ₂ O ₃ ingredient ratio X (iron oxide / metal iron) (weight ratio)

Figure 3 shows the slag generation rate according to the temperature in the furnace, the slag is the slag obtained during the tapping process and the slag layer recovered from the furnace after the experiment was measured. The slag contains the amount of unreacted dust, which is because it is not possible to separate only dust in the middle because it is already mixed with powdered coke. As the temperature increased, the slag generation decreased.

ingredient SiO ₂ CaO Al ₂ O ₃ MgO Na ₂ O K ₂ O ZnO Pb Fe ₂ O ₃ CD FeO weight% 4.91 8.35 0.99 2.11 1.80 1.92 24.23 2.48 39.70 0.02 1.72

As can be seen from FIG. 2, it can be seen that the recovery amount of iron is increased as the temperature of the furnace 2 increases. This is because iron oxide tends to become metal as the temperature increases, so the slag amount decreases, but the recovery amount of metal iron seems to increase.

However, the recovery rate increase rate is not large at 1400 ℃ or more, it can be seen that it is most preferable to increase the temperature in the temperature range 1200 ~ 1400 ℃.

3 shows the amount of zinc recovered when the temperature of the zinc collecting device 5 is fixed at 400 ° C., 430 ° C., 450 ° C., 470 ° C., 500 ° C., 520 ° C. and 550 ° C., respectively. Since zinc contained in dust is composed of ZnO state, pure zinc is in the form of one oxygen and one zinc atom combined. Therefore, about 80% of ZnO can be recovered as metallic zinc in terms of weight ratio. Obtained together.

Theoretical recoverable amount = (loading amount-coke amount) x ZnO content ratio x zinc oxide / metal zinc (weight ratio)

As can be seen from FIG. 4, since the amount of zinc recovered is parabolic, a proper recovery section exists. The maximum recovery was obtained when the temperature of the zinc collector was maintained at about 470 ° C.

However, as the temperature of the furnace increases, it is easier to reduce valuable metals such as iron and zinc to the metal state.However, as the temperature increases, the gas volume increases to increase the flow velocity in the furnace, thereby controlling the temperature of the zinc collecting device. Since it has a difficult disadvantage, it can be seen that it is economical to recover the zinc in conjunction with the furnace temperature in the appropriate temperature range of about 430 ~ 500 ℃.

Example 2

This embodiment is an embodiment for recovering the valuable metal from the secondary dust generated by treating the dust by-product generated in the electric furnace unlike Example 1.

The chemical composition of the secondary dust is shown in Table 2. In this example, the powder is prepared to contain 1% of powdered coke, containing 8% of fine powdered coke as a reducing agent, and evenly mixing limestone for adjusting the basicity to about 3%. The mixture was charged with 70 kg of electrolytic iron to facilitate plasma generation.

SiO ₂ CaO Al ₂ O ₃ MgO Na ₂ O KCl ZnO PbO Fe ₂ O ₃ CD MnO Cr ₂ O ₃ NiO Ig loss 6.32 7.70 2.00 7.00 3.45 22.50 24.81 5.46 9.12 0.12 2.90 2.51 0.74 7.00

The method of calculating the recovery rate of the other metal iron is the same as in Example 1, but the result is that in the case of the present embodiment as shown in Fig. 5 when the temperature is raised to 1400 ℃ or more, the recovery rate of iron metal decreases, as shown in FIG. Rather increasing, it can be seen that it is most preferable to increase the temperature to 1200 ~ 1400 ℃.

On the other hand, the zinc test by the zinc trapping device was carried out in the same manner as in Example 1, the results are the same as in Figure 4, the result of Example 1 zinc recovery was the best in the temperature range of 430 ~ 500 ℃ Same.

Therefore, according to the present invention as described above, the recovery rate of metal iron by melting the industrial wastes by heating the industrial wastes such as primary dust and secondary dust in the closed melting furnace to heat the industrial wastes such as primary dust and secondary dust It is possible to reduce and recover the contained zinc oxide component in the metal state and improve the recovery rate.

Claims (3)

A method for recovering valuable metals from industrial wastes by applying power between the cathode rod and anode of plasma generating furnace to heat the furnace temperature to 1200 ~ 1400 ℃ by heat generated by converting gas into plasma to dissolve industrial wastes. A method for recovering valuable metals from industrial wastes using plasma. The method for recovering valuable metals from industrial wastes according to claim 1, wherein the industrial wastes are electric dust or secondary dusts generated during dust treatment. The method for recovering valuable metals from industrial wastes according to claim 1 or 2, wherein the metal zinc is recovered from the zinc vapor generated at the time of dissolving industrial wastes through a zinc collecting device at 430 to 500 ° C.