KR101222533B1 - Device for recycling zinc oxide using zinc by-product - Google Patents

Abstract

PURPOSE: A zinc oxide recycling apparatus using zinc byproducts is provided to cool zinc byproducts through a plurality of heating zones where different heating temperatures are set according to the types of impurities in the zinc byproducts, thereby effectively removing the impurities. CONSTITUTION: A zinc oxide recycling apparatus using zinc byproducts comprises a chamber unit(110) and a feed housing unit(130). The chamber unit includes an inner chamber(111), an outer chamber enclosing the inner chamber and increasing the temperature of the inner chamber, and a heating unit(115) connected to the outer chamber and heating the air between the inner and outer chambers. The feed housing unit includes a feed housing(131) connected to the chamber unit and provided with zinc byproducts and a large-diameter screw(133) connected to the feed housing and rotated to feed the zinc byproducts into the inner chamber. [Reference numerals] (AA) Progressing direction

Description

Device for recycling zinc oxide using zinc by-product}

The present invention relates to a zinc oxide recycling apparatus using zinc by-products, and more particularly, zinc oxide using zinc by-products that can extract zinc oxide having a small amount of impurities from by-products containing zinc oxide that is discarded to the outside. It relates to a recycling apparatus.

Recently, a technology for extracting iron and zinc from wastes and recycling them by using a rotary kiln combustion furnace used to burn and dispose of renewable fuels has been developed.

In particular, the technology of extracting zinc, a natural resource of oil price, from steelmaking dust, which has been classified as a hazardous waste, has been newly illuminated. ought.

Rotary kiln furnace is briefly described as a large cylinder is installed slightly inclined to rotate at a slow speed while blowing the flame (flame) from the bottom, the raw material is injected from the top. However, when the waste is injected from the upper side and the flame is blown from the lower side, the waste is directly heated to the flame, which causes a problem that the waste is damaged by the high temperature flame.

In addition, since the temperature inside the rotary kiln is not kept constant, the ability to remove impurities from the waste is low, and as described above, it is difficult to extract zinc having a low content of impurities so that recycling is possible.

Therefore, it is possible to solve the problems of the rotary kiln combustion furnace as described above, and in particular, the development of a technology capable of extracting zinc with a low content of impurities to enable recycling is necessary.

Republic of Korea Patent No. 10-0758993

The present invention uses a rotary kiln type as described above, while zinc oxide can be extracted by removing impurities other than zinc from zinc by-products, while the combustion temperature can be controlled according to the types of impurities contained in zinc by-products. It is an object of the present invention to provide a zinc oxide recycling apparatus using zinc by-products that can safely discharge the gas produced when the impurities are burned.

The present invention includes an inner chamber through which the inner chamber penetrates, an outer chamber surrounding the inner chamber and increasing a temperature of the inner chamber, and a heating connected to the outer chamber to heat air between the inner chamber and the outer chamber. A chamber unit having means; And an input housing unit connected to the chamber unit and having an input housing into which zinc by-products are introduced, and a large diameter screw which is in communication with the input housing and rotated to introduce the zinc by-products into the internal chamber. The unit is provided with a plurality, the internal chambers are connected to communicate with each other, and the zinc by-products are sequentially passed through the chamber unit to provide a zinc oxide recycling apparatus using zinc by-products in which impurities other than zinc are vaporized.

Zinc oxide recycling apparatus using zinc by-product according to the present invention has the following effects.

First, because the by-product chamber is heated to heat the zinc by-product, the flame does not directly contact the zinc by-product, preventing the zinc by-product from being damaged by the hot flame and extracting only the lead oxide from which impurities are removed. Can have an effect.

Second, since the zinc by-products are heated while passing through the plurality of heating zones, the heating temperatures of the plurality of heating zones may be set differently according to the types of impurities included in the zinc by-products, thereby removing impurities more effectively.

Third, since the gas generated while the impurities are vaporized is discharged to the outside through the exhaust hood, the environment can be prevented from being contaminated by the gas, and the exhaust hood is provided to explode the zinc oxide recycling apparatus using zinc by-products. It can have the effect of preventing the risk of.

1 is a side view showing a zinc oxide recycling apparatus using zinc by-product according to an embodiment of the present invention.
2 is an exploded side view illustrating a zinc oxide recycling apparatus using zinc by-products according to FIG. 1.
FIG. 3 is a block diagram illustrating a part of a zinc oxide recycling apparatus using zinc by-products according to FIG. 1.
4 is a block diagram illustrating a process of extracting zinc oxide using a zinc oxide recycling apparatus using zinc by-products according to FIG. 1.

1 to 3 relates to a zinc oxide recycling apparatus using zinc by-products according to an embodiment of the present invention. 1 to 3, a zinc oxide recycling apparatus using zinc by-products includes a chamber unit 110 and an input housing unit 130. Here, zinc by-products may be used as various zinc by-products, but in this embodiment, zinc by-products from smelters are defined.

 The chamber unit 110 includes an inner chamber 111, an outer chamber 113, and a heating means 115. The inner chamber 111 penetrates inside and is formed in a cylindrical shape. The outer chamber 113 is formed to surround the inner chamber 111, wherein the inner circumferential surface of the inner chamber 111 and the inner circumferential surface of the outer chamber 113 are spaced apart to form a spaced space. 111 is formed to surround the surrounding. The outer chamber 113 is formed to heat the inner chamber 111 to increase the temperature inside the inner chamber 111. The heating means 115 is connected to the outer chamber 113. The heating means 115 may be separately installed outside the outer chamber 113 and connected to the outer chamber 113, that is, the inner chamber 111, that is, the inner chamber 111 and the outer chamber 113. It may be provided between the (113).

The heating means 115 is filled with air in the space space between the inner chamber 111 and the outer chamber 113 serves to warm the air by the heating means 115. The inner chamber 111 is heated while the air filled in the separation space between the inner chamber 111 and the outer chamber 113 is heated by the heating means 115.

Meanwhile, when the heating means 115 is installed between the inner chamber 111 and the outer chamber 113, the heating means 115 directly heats the inner chamber 111. The heating means 115 may be provided as an electric heater or a gas heater.

As will be described later, the inner chamber 111 is heated through the outer chamber 113 and the heating means 115 to increase the internal temperature of the inner chamber 111. Zinc oxide by-products are introduced into the inner chamber 111 to increase the temperature inside the inner chamber 111, thereby heating the zinc oxide by-products.

As described above, a plurality of chamber units 110 are provided, and the plurality of chamber units 110 are connected to communicate with each of the inner chambers 111. The plurality of chamber units 110 form a plurality of heating zones including at least one or more chamber units 110. 1 and 2, in the present embodiment, a first heating zone A including at least one chamber unit 110 and a second heating zone B including at least one chamber unit 110 are provided. ) Is formed. However, as described above, the heating zones need not be limited to two heating zones as in the present embodiment, and more heating zones may be formed. Hereinafter, the first heating zone (A) and the second heating zone (B) will be described as an example to aid in understanding the invention.

The first heating zone A and the second heating zone B are not connected in parallel, but are inclined downward from the first heating zone A toward the second heating zone B. Therefore, the zinc oxide by-product introduced through the input housing unit 130 to be described later moves, and the progress direction in which the process of extracting only zinc oxide while the zinc oxide by-product is heated is performed as shown in FIGS. 1 and 2. The direction from the first heating zone (A) toward the second heating zone (B).

The input housing unit 130 includes an input housing 131 and a large diameter screw 133. Zinc oxide by-products are injected into the input housing 131. In general, a worker injects zinc oxide by-products into the input housing 131. The large diameter screw 133 communicates with the inlet housing 131 and is also connected to the chamber unit 110. The large diameter screw 133 rotates and introduces zinc oxide by-product introduced through the input housing 131 into the chamber unit 110.

On the other hand, the large diameter screw 133 may be connected to be in direct communication with the inner chamber 111 of the chamber unit 110, as shown in Figures 1 and 2, the interior through the connection housing 135 It may be connected to communicate with the chamber 111. In the present embodiment, a pre-heating zone is formed by the connection housing 135, and the pre-heating zone removes water that may be mixed with the zinc oxide by-product introduced through the input housing unit 130, thereby oxidizing the oxidation. Zinc by-products can be easily moved by the large screw (133).

The input housing unit 130 is connected to the front end of the first heating zone A and the first heating zone A formed by the plurality of chamber units 110. do. The zinc oxide by-product introduced through the input housing unit 130 is directed from the first heating zone A to the second heating zone B through the large diameter screw 133 of the input housing 130. Inflow to move to.

Impurities other than zinc oxide included in the zinc oxide by-product are vaporized (removed while being heated) from the first heating zone A to the second heating zone B, and the gas generated while the impurities are vaporized is Zinc oxide by-products flow in the opposite direction to the direction in which they travel. Since the plurality of chamber units 110 are disposed to be inclined downward from the first heating zone A to the second heating zone B, the zinc oxide by-products are caused to gravity by the first heating zone A. In the second heating zone (B) is easy to move, the gas generated while the impurities contained in the zinc oxide by-products evaporate flows to a high place by the first heating zone in the second heating zone (B) Flow into zone A.

The heating temperature for heating the inner chamber 111 of the first heating zone A and the heating temperature for heating the inner chamber 111 of the second heating zone B may be the same or may be the same. The heating temperature of the second heating zone (B) may be set higher than the heating temperature of the first heating zone (A). Therefore, the heating temperature of the first heating zone (A) and the heating temperature of the second heating zone (B) are determined according to the types of impurities other than zinc oxide contained in the zinc oxide by-product.

In general, the heating temperature of the second heating zone (B) is set higher than the heating temperature of the first heating zone (A), and when the zinc oxide by-product passes through the first heating zone (A), Part of the impurities other than zinc oxide contained in the zinc oxide by-product is vaporized, and when passing through the second heating zone (B), the other impurities other than zinc oxide contained in the zinc oxide by-product are vaporized.

On the other hand, when the first heating zone (A) and the second heating zone (B) is formed of a plurality of chamber units 110, respectively, the heating temperature and the second heating zone of the first heating zone (A) The heating temperature of (B) may be set for each chamber unit 110. That is, for example, when the first heating zone A is formed of three chamber units 110, the temperatures at which the three internal chambers 111 are heated may be set differently. This case can be applied when there are many kinds of impurities except zinc oxide included in the zinc oxide by-product, and the temperatures at which the impurities are vaporized are different from each other.

The inside of each of the inner chambers 111 is heated so that the air filled in the space between the inner chamber 111 and the outer chamber 113 is heated by the heating means 115 rather than being heated by the heating means 115. The heating means 115 is directly installed in the space between the chamber 111 and the outer chamber 113 to directly heat the inner chamber 111.

On the other hand, the exhaust hood 150 is connected to the first heating zone (A). That is, the exhaust hood 150 is positioned between the first heating zone A and the input housing unit 130 to form the first heating zone A, and the inner chamber of the chamber unit 110. It is connected to communicate with (111).

As described above, when the zinc oxide by-product is heated while passing through the first heating zone (A) and the second heating zone (B), the gas generated as the impurities other than zinc oxide in the zinc oxide by-product are vaporized. Zinc oxide by-products flow in the reverse direction of travel. That is, it flows in the direction toward the first heating zone A and the input housing unit 130. Therefore, the exhaust hood 150 is installed between the first heating zone A and the input housing unit 130 so that the gas flows through the first heating zone A and toward the input housing unit 130. Is discharged through the exhaust hood 150 before flowing to the input housing unit 130.

The gas generated by vaporization of impurities other than zinc oxide of the zinc oxide by-product may include very fine particles because it is a gaseous state or a gas generated by vaporizing a metal. Therefore, when the gas flows into the input housing unit 130, the gas may be entangled with the large diameter screw 133 of the input housing unit 130, which may cause a failure of the large diameter screw 133. . Therefore, as described above, allowing the gas to be discharged through the exhaust hood 150 before the gas flows to the input housing unit 130 may have an effect of preventing the failure of the large diameter screw 133.

In addition, if the gas generated by the vaporization of impurities is not discharged, the gas remains in the internal chamber 111 of the chamber unit 110, and when the amount of the generated gas increases, the plurality of connected chamber units 110 may explode. Problems may arise. Therefore, when the gas is discharged through the exhaust hood 150, the interior chamber 111 may not be expanded due to the gas, thereby preventing the plurality of connected chamber units 110 from being exploded.

Meanwhile, a cooling zone C is formed at the point where the second heating zone B ends. The cooling zone C is formed by the cooling units 141 and 143 connected in communication with the inner chamber 111 of the chamber unit 110 forming the second heating zone B, and the cooling unit 141 and 143 include a housing 141 and a cooler 143 connected to the housing 143.

The zinc oxide by-product passes through the first heating zone (A) and the second heating zone (B) and vaporizes only impurities except zinc oxide, leaving only zinc oxide, wherein the zinc oxide is the first heating zone (A). ) And being heated while passing through the second heating zone B, are moved to the cooling zone C and cooled. Therefore, after cooling the zinc oxide in the cooling zone (C), the operator can extract the zinc oxide.

Referring to FIG. 3, a zinc oxide recycling apparatus using zinc by-products includes an input unit for operating the heating means 115, the large diameter screw 133, the exhaust hood 150, and the cooler 143. 160 and the controller 170 may be further included. The input unit 160 is an operator inputs a command to operate the heating means 115, the large diameter screw 133, the exhaust hood 150 and the cooler 143, the form of a remote control or touch panel. It may be provided as. The control unit 170 operates the heating means 115, the large diameter screw 133, the placement hood 150, and the cooler 143 according to an operation command input through the input unit 160.

That is, when an operator inputs an operation command to the input unit 160, the control unit 170 first rotates the large diameter screw 133 to feed the zinc oxide by-products into the first heating zone A and the second heating zone. (B) and when the zinc oxide by-products move the first heating zone (A) and the second heating zone (B), the heating means (115) is operated to heat the zinc oxide by-products and oxidize them. Vaporize impurities other than zinc. In addition, the exhaust hood 150 is operated to discharge gas generated as the impurities are vaporized to the outside, and the cooler 143 operates to cool the zinc oxide remaining after the impurities are removed.

1 and 2, the zinc oxide recycling apparatus using zinc by-products further includes a work frame 10 and a ladder 30 to install the zinc oxide recycling apparatus using zinc by-products in a production line of a factory. It may include. As shown in the drawing, the working frame 10 includes the first heating zone A and the second heating zone B from the first heating zone A to the second heating zone B. FIG. It is formed so that it can be disposed downward inclined gradually. On the upper side of the work frame 10 is installed a scaffold for the worker to move, when the need for repair of the zinc oxide recycling apparatus using the zinc by-products, such as the worker is moved to the scaffold to recycle zinc oxide using the zinc by-products The device can be repaired.

Since the work frame 10 is formed to have a predetermined height from the bottom, as shown in the figure, the ladder 30 is placed on both sides of the work frame 10 by the operator to the footrest of the work frame 10. It is installed to move to. As described above, the input unit 160 is installed in the form of a touch panel on the work frame 10, so that the chamber unit 110, the input housing unit 130, and the exhaust hood ( 150) and the cooler 143 and the like may be electrically connected to each other.

4 illustrates a process of extracting zinc oxide through a zinc oxide recycling apparatus using zinc by-products according to an embodiment of the present invention. Referring to FIG. 4, in the zinc oxide extraction process, zinc oxide by-products containing zinc oxide and impurities are first introduced through the input housing unit 130 (step S205). An operator inserts the zinc oxide by-products into the input housing. It is input to the input housing 131 of the unit 130, and the operation command is input through the input unit 160. When the operation command is input to the input unit 160, the controller 170 rotates the large diameter screw 133 of the input housing unit 130, the large diameter screw 133 is rotated, the zinc oxide by-products are shown in Figure 1 and It is moved along the traveling direction shown in FIG. 2 (step S210).

The zinc oxide byproduct is moved along the connection housing 135 and may be dried while moving the connection housing 135. The zinc oxide by-product is moved to the first heating zone A in the connection housing 135, and the inner chamber 111 of the chamber unit 110 forming the first heating zone A is connected to the connection housing ( It is connected in communication with the 135 and moves from the connection housing 135 to the inner chamber 111. The heating means 115 of the chamber unit 110 heats the inner chamber 111 while the zinc oxide by-product moves through the first heating zone A.

The zinc oxide by-product that moves the first heating zone A is also heated while the inner chamber 111 is heated. As the zinc oxide by-product is heated, some of the impurities other than the zinc oxide are vaporized. (S215) At this time, gas is generated as the impurities are vaporized, and the gas is in a direction opposite to the direction in which the zinc oxide by-product moves. Flows into.

On the other hand, the zinc oxide by-product passing through the first heating zone (A) is moved to the second heating zone (B). In the second heating zone B, impurities other than zinc oxide are vaporized in the zinc oxide by-product through the same process as in the first heating zone A (step S215), and the gas generated by the vaporized impurities is The zinc oxide by-product flows in a direction opposite to the direction in which it moves. The gas generated by the vaporization of the impurities flows in a direction toward the input housing unit 130 and is externally provided through an exhaust hood 150 installed between the first heating zone A and the input housing unit 130. Is discharged to. (Step S220)

Zinc oxide from which the impurities are removed while passing through the first heating zone A and the second heating zone B is moved from the second heating zone B to the cooling zone C, and the cooling zone By cooling by the cooler 143 inside the housing 141 of C), the zinc oxide extraction process is finished (step S225).

When the zinc oxide recycling apparatus using zinc by-products according to the present invention is applied, zinc oxide by-products may have an effect of recycling zinc oxide by-products by removing only zinc oxide by removing impurities except zinc oxide. In particular, in the process of moving the zinc oxide by-product to be heated, the heating step is divided into a plurality of circuits to adjust the temperature according to the type of impurities contained in the zinc oxide by-product, thereby extracting zinc oxide more effectively.

In addition, the chamber unit for heating the zinc oxide by-products moves through the inner chamber by heating the inner chamber by wrapping the inner chamber on the outside of the inner chamber rather than directly heating the zinc oxide by-product in the inner chamber where the zinc oxide by-product is moved. Since the zinc oxide by-product is heated, it may have an effect of preventing a problem that a fire may occur when the zinc oxide by-product is directly heated.

The gas generated by vaporization of impurities other than zinc oxide contained in zinc oxide by-products can be discharged to the outside through the exhaust hood, thereby preventing failure of the zinc oxide by-products in the zinc oxide recycling apparatus. In addition, by connecting the exhaust line of the factory and the exhaust hood to effectively discharge the gas to prevent the occurrence of environmental pollution.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: chamber unit 111: inner chamber
113: outer chamber 115: heating means
130: input housing unit 131: input housing
133: large diameter screw
141: housing 143: cooler
150: exhaust hood 160: input unit
170:

Claims (9)

An inner chamber through which the inner chamber penetrates, an outer chamber surrounding the inner chamber to increase the temperature of the inner chamber, and heating means connected to the outer chamber to heat air between the inner chamber and the outer chamber; Chamber unit; And
An input housing unit connected to the chamber unit and having an input housing into which zinc oxide by-products are introduced, and a large diameter screw which is in communication with the input housing and rotated to introduce the zinc oxide by-products into the inner chamber,
The chamber unit is provided with a plurality, the internal chambers are connected to communicate with each other, the zinc oxide by-products are sequentially passed through the chamber units, impurities other than the zinc oxide is vaporized,
The plurality of chamber units connected to communicate with the inner chambers are disposed to be inclined downward in a direction away from the input housing unit, and at least two heating zones are formed by the plurality of chamber units.
Each heating zone comprises at least one said chamber unit,
The zinc oxide by-products are moved in a downwardly inclined direction by gravity and pass through the two or more heating zones, pass through the two or more heating zones, and the gas generated by the vaporization of the impurities causes the zinc oxide by-products to be moved. Zinc oxide recycling equipment using zinc by-products flowing in opposite directions. delete The method according to claim 1,
A cooling unit connected to a front end of the plurality of chamber units facing the input housing unit to cool the zinc oxide extracted from the zinc oxide by-product,
A zinc oxide recycling apparatus using zinc by-products in which a cooling zone is formed by the cooling unit. The method according to claim 1,
The heating means is a zinc oxide recycling apparatus using zinc by-products including an electric heater or a gas heater. The method according to claim 1,
The heating temperature of each of the heating zones increases as the two or more heating zones move away from the input housing unit side,
The zinc oxide by-products are zinc oxide by-products are recycled by using the zinc by-products are gradually removed as the impurities are gradually evaporated each passing through each heating zone. The method according to claim 5,
A zinc oxide recycling apparatus using zinc by-products, wherein the heating temperature of each heating zone is determined according to the type of the impurities. The method according to claim 1,
The two or more heating zones are zinc oxide recycling apparatus using zinc by-products are all maintained at the same heating temperature. The method according to claim 1,
The apparatus for recycling zinc oxide using zinc by-products further includes an exhaust hood for discharging the gas generated while the impurities are vaporized between the chamber unit and the input housing unit. The method according to claim 1,
When each heating zone is formed of a plurality of the chamber units,
The zinc oxide recycling apparatus using zinc by-products, wherein the heating temperature of each heating zone is set differently for each of the chamber units.

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