KR20160025131A - Scrap preheating for electric arc furnace and it's operation method - Google Patents

Abstract

The present invention relates to an alternate-type scrap preheating apparatus for an electric arc furnace; a preheating method; an electric arc furnace having the scrap preheating apparatus; and an operation method capable of reducing power consumption of an electric arc and handling bad smell generated when an iron scrap is preheated by preheating the iron scrap using a high temperature exhaust gas sensible heat, non-reacted chemical energy of the exhaust gas, and an appropriate amount of auxiliary heat source. In detail, an iron scrap preheating apparatus installed as at least one in an electric arc furnace main body, and allowing for a gas flow with an interior of the electric arc furnace main body comprises: a housing provided on one side of the main body, having an internal space; a partition dividing an upper portion of the internal space of the housing into at least one first preheating chamber and at least one second preheating chamber; a buffer unit positioned on a lower end of the internal space of the housing; and an introduction unit charging a scrap introduced to the buffer unit into the main body. When the first preheating chamber is in a preheating combustion mode, the second preheating chamber is operated in a charge preheating mode; and when the first preheating chamber is in the charge preheating mode, the second preheating chamber is operated in the preheating combustion mode. The first preheating chamber, wherein a scrap is charged in an internal space thereof, includes a first air-permeable finger opening and closing a lower end and a first preheating combustor to preheat the charged scrap. The second preheating chamber, wherein the scrap is charged in an internal space thereof, includes a second air-permeable finger opening and closing a lower end, and a second preheating combustor to preheat the charged scrap.

Description

TECHNICAL FIELD [0001] The present invention relates to an electric arc furnace and an electric arc furnace equipped with the scrap heat preheating device,

The present invention relates to an alternating-type scrap preheating apparatus for electric arc furnaces, a preheating method, an electric arc furnace equipped with the scrap preheating apparatus, and a method of operating the same. More specifically, by preheating iron scrap using the sensible heat of the high temperature flue gas of the electric arc furnace, the unreacted chemical energy in the flue gas, and an appropriate amount of auxiliary heat source, it is possible to reduce the electric power consumption of the electric arc furnace, The present invention relates to a preheating apparatus and a method of operating the same.

The electric arc furnace is an electric energy dissipation facility that produces high-voltage arc to dissolve various quality scrap (steel scrap) to produce steel. In order to reduce the electric energy consumption of the electric arc furnace, it is preferable to preheat the iron scrap to a high temperature as high as possible and to put it into an electric furnace. In general, a method of preheating the iron scrap using the sensible heat of the exhaust gas discharged from the electric arc furnace have. However, steel scrap has various composition and quality. Especially, it is in contact with various machine oils or treated with coating materials, so it is inevitable that harmful harmful substances (dioxins, furans, etc.) It is becoming a target. Therefore, at present, in Korea, the steel scrap is directly charged by opening the top of the electric arc without performing any pretreatment including preheating of the iron scrap, so that cooling and reheating are repeated due to the discharge of high temperature thermal energy in the electric arc It is difficult to expect the thermochemical energy and electric energy savings.

Fig. 1 shows a process diagram (energy utilization flowchart) of a conventional electric arc furnace. As shown in Fig. 1, an electric arc furnace generally comprises a power supply including an arc-generating electrode 1 for melting iron scrap, a carbon injector 2 for reducing oxidized iron scrap 2, an iron scrap melting / (3) for the secondary combustion for the recovery of unreacted chemical energy (carbon monoxide and hydrogen) generated in the furnace, an oxygen combustor (4) for heating the low temperature part inside the furnace and for further heating of the scrap iron, (6) for removing pollutants or odors in the exhaust gas, a dust removing device for removing dust, and a dust removing device A bag filter 7, an exhaust fan 8, and the like.

In such a conventional electric arc furnace, the preheating of the iron scrap is entirely dependent on the high temperature exhaust gas discharged from the electric arc furnace body. The exhaust gas is directly exchanged by contact with the iron scrap filled in the preheater and the temperature of the exhaust gas And the temperature of the iron scrap also varies depending on the position. That is, the preheating temperature of the iron scrap near the outlet of the electric arc furnace (the bottom of the preheater) is relatively high due to the contact with the relatively high temperature exhaust gas, while the preheating temperature of the iron scrap located at the outlet end of the preheater (the top of the preheater) is relatively low. In order to reduce electric energy consumption and stable operation, it is required to supply uniformly preheated iron scrap as high as possible, while the fluctuation of the preheating temperature of the iron scrap causes fluctuation of the electric arc intensity for dissolution, .

In addition, since the temperature of the exhaust gas passing through the preheater is also lowered, it is necessary to supply a stable secondary combustion for recovery of unreacted chemical energy such as low concentration of carbon monoxide contained in the exhaust gas and an appropriate amount of auxiliary heat source for removing pollutants or odors from the exhaust gas. Which leads to limitations.

Therefore, preheating of high-temperature scrap of iron scrap, elimination of bad smell generated, unreacted chemical energy in exhaust gas can be effectively recovered and utilized, and an iron scrap preheater capable of closing the electric arc can be used for electric arc furnace You can contribute.

Korea Patent No. 1129758 Korean Patent No. 868506 Korean Patent Publication No. 10-2001-0005563

Accordingly, it is an object of the present invention to provide a preheater for an iron scraper, which is operated in sequence and repeatedly by operating a plurality of preheaters, each using a separate auxiliary heat source, (CO) contained in the exhaust gas discharged from the furnace body and H ₂ (hydrogen (H ₂ )) contained in the flue gas discharged from the furnace body are supplied to the upstream side of the plurality of scrap preheaters. The flue gas is mixed with the hot flue gas discharged from the main body of the electric arc furnace, ) Is provided to increase the temperature of the flue gas by installing a secondary combustion device for converting the unreacted chemical energy into thermal energy, thereby simultaneously raising the preheating temperature of the scrap and the incineration of the smell at high temperature.

The remaining heat that passes through each preheater is used for preheating the oxidant for the secondary heat of the preheater and the fuel for the auxiliary heat source of the preheater and the oxidizer for the secondary combustion of the preheater through a separate heat recovery device to improve the combustion efficiency (control of combustibility) Depending on the operating conditions, ie, the quality of the iron scrap, the pretreatment of the iron scrap, and the conditions of the final mixed flue gas in the electric furnace, the auxiliary heat source supply amounts required for the plurality of preheaters, the secondary combustion devices and the electric furnace main body are actively and freely interlocked Thereby providing an adjustable system.

In addition, since the electric arc furnace body can be closed, cooling and reheating of the inside of the electric arc furnace due to opening of the electric arc furnace upper end to prevent the scrap iron can be prevented, so that the thermochemical energy and electric energy consumption can be expected to be reduced.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments with reference to the accompanying drawings.

A first object of the present invention is to provide an iron scrap preheater comprising at least one electric arc furnace body and gas flowable inside the electric arc furnace body, the iron scrap preheating apparatus comprising: a housing provided at one side of the main body and having an internal space; A partition wall partitioning the upper part of the inner space of the housing into at least one first preheating chamber and at least one second preheating chamber; A buffer unit located at a lower end of the inner space of the housing; And a charging means for charging the scrap introduced into the buffer portion into the main body. When the first preheating chamber is in the preheating combustion mode, the second preheating chamber is operated in the charging preheating mode, and the first preheating chamber is charged Wherein the first preheating chamber is operated in a preheating combustion mode when the first preheating chamber is in the preheating mode, the first preheating chamber includes a first air permeable finger charged with scrap in the inner space and opening and closing the lower end, And a second preheating combustor for preheating the charged scrap, wherein the second preheating chamber includes a second air-permeable finger charged with scrap in the inner space and opening / closing the lower end thereof, and a second preheating combustor for preheating the charged scrap Can be achieved as an alternating scrap preheating device for an electric arc furnace.

In the first object of the present invention, when the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode, the breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated And the preheating chamber exhaust gas flows into the preheating chamber in the charging preheating mode, and when the first preheating chamber or the second preheating chamber operates in the charging preheating mode, the preheating chamber And the exhaust gas discharged from the electric furnace main body flows into the preheating chamber, which is a charging preheating mode, and is exhausted.

The first object of the present invention is to further include a secondary combustion device for converting the unreacted chemical energy of the exhaust gas of the main body of the electric furnace into the preheating chamber, .

A second object of the present invention is to provide an iron scrap preheating apparatus in which at least one iron core is installed in an electric arc furnace main body and is capable of flowing gas into the electric arc furnace main body, At least one first preheating chamber having a first air permeable finger for opening and closing, and a first preheating combustor for preheating charged scrap; And at least one second preheating chamber provided on the other side of the main body and having a second air-permeable finger charged with scrap in the inner space and opening / closing the lower end portion, and a second preheating combustor for preheating charged scrap The second preheating chamber is operated in a charging preheating mode when the first preheating chamber is in the preheating combustion mode and the second preheating chamber is operated in the preheating combustion mode when the first preheating chamber is in the charging preheating mode As a scraper preheating device for an electric arc furnace.

In the second object of the present invention, when the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode, the breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated The preheating chamber exhaust gas flows into the preheating chamber through the inside of the main body, and when the first preheating chamber or the second preheating chamber is operated in the charging preheating mode, The breathable fingers of the preheating chamber which is the charging preheat mode are opened so that the scrap charged in the space of the preheating chamber flows into the main body and the exhaust gas in the main body flows into the preheating chamber which is the charging preheating mode and is exhausted.

In a second aspect of the present invention, there is provided a method for converting unreacted chemical energy of an exhaust gas in a main body, which is provided at an inner lower end of the first preheating chamber and the second preheating chamber into a preheating chamber, And a secondary combustion device.

The first and second objects of the present invention may further include a retractable cover provided at each of the upper ends of the first preheating chamber and the second preheating chamber for loading scrap.

In the first and second objects of the present invention, there is provided a fuel cell system including: a first supply pipe for supplying an oxidant and a fuel to a first preheating combustor which is a preheat combustion mode; and a second supply pipe for supplying an oxidant and a fuel to a second preheat combustor A first exhaust pipe provided in the first preheating chamber and exhausted from the main exhaust gas flowing into the first preheating chamber which is provided in the first preheating chamber and the preheating chamber exhaust gas, and a second preheating pipe provided in the second preheating chamber, And a second exhaust pipe through which the main exhaust gas and the preheating exhaust gas are exhausted.

In the first and second objects of the present invention, there is provided a fuel cell system comprising: a supply pipe connected to a preheating combustor, which is a preheating combustion mode; and an oxidizing agent, which is connected to an exhaust pipe of a preheating chamber, And a heat exchanger for exchanging heat with the exhaust gas exhausted through the exhaust pipe of the preheating chamber, which is the charging preheating mode.

A third object of the present invention is to provide a scrap preheating method using an alternating scrap preheating apparatus for an electric arc furnace in which an internal space is partitioned into a first preheating chamber and a second preheating chamber by partition walls and a buffer unit is provided in a lower internal space, A first step in which the first preheating chamber is opened by the breathable fingers and the preheated scrap already charged in the first preheating chamber is injected into the buffer part; A second step in which flue gas in the main body flows into the buffer unit and the first preheating chamber; The second preheating combustor is operated to preheat the scrap in the second preheating chamber and the second preheating chamber exhaust gas flows into the first preheating chamber via the buffer portion so that the first preheating chamber is in the charge preheating mode and the second preheating chamber is preheated A third step of operating in a mode; The operation of the second preheating combustor is stopped, the first preheating chamber is closed by the first air-permeable fingers, the second preheating chamber is opened by the second air-permeable fingers to be charged and discharged in the second preheating chamber, A fourth step in which the preheated scrap is injected into the buffer unit; A fifth step in which flue gas in the main body flows into the buffer unit and the second preheating chamber; The first preheating combustor is operated to preheat the scrap in the first preheating chamber and the first preheating chamber exhaust gas flows into the second preheating chamber via the buffer portion so that the first preheating chamber is in the preheating combustion mode and the second preheating chamber is charged preheating A sixth step of operating in a mode; And repeating the first, second, third, fourth, fifth, and sixth steps. The scrape preheating method using the scraper preheating apparatus for an electric arc furnace .

In the third aspect of the present invention, the method may further include the step of converting the unreacted chemical energy of the main exhaust gas flowing into the preheating chamber, which is a charging preheating mode, into thermal energy by the secondary combustion device provided in the buffer unit can do.

A fourth object of the present invention is to provide a scrap preheating method using a scraper preheating apparatus for an electric arc furnace having a first preheating chamber provided on one side of an electric arc furnace body and a second preheating chamber provided on the other side, A first step in which the first preheating chamber is opened and the scrap charged in the first preheating chamber is injected into the main body; A second step in which flue gas in the main body flows into the first preheating chamber; The second preheating combustor is operated to preheat the scrap in the second preheating chamber and the second preheating chamber exhaust gas flows into the first preheating chamber through the inside of the main body so that the first preheating chamber is preheated A third step of operating in a combustion mode; After the lapse of a predetermined time, the operation of the second preheating combustor is stopped, the first preheating chamber is closed by the first breathable fingers and the second preheating chamber is opened by the second breathable fingers, A fourth step of putting scrap into the main body; A fifth step in which flue gas in the main body flows into the second preheating chamber; The first preheating combustor is operated to preheat scrap in the first preheating chamber and the first preheating chamber exhaust gas flows into the second preheating chamber through the inside of the main body so that the first preheating chamber is preheated and the second preheating chamber is charged A sixth step of operating in a preheating mode; And repeating the first, second, third, fourth, fifth, and sixth steps. The scrape preheating method using the scraping scraper preheating apparatus for an electric arc furnace .

In a fourth aspect of the present invention, the second step includes the step of converting the unreacted chemical energy of the main exhaust gas flowing into the first preheating chamber into heat energy by the secondary combustion device provided at the lower end of the first preheating chamber And the fifth step further comprises the step of converting the unreacted chemical energy of the main exhaust gas flowing into the second preheating chamber into the thermal energy by the secondary combustion device provided at the lower end of the second preheating chamber .

In the third and fourth objects of the present invention, the first residual amount measuring unit provided in the first preheating chamber measures a residual amount of scrap charged in the first preheating chamber; And measuring a remaining amount of scrap charged in the second preheating chamber by a second remaining amount measuring unit provided in the second preheating chamber.

In the third and fourth aspects of the present invention, when it is determined that the residual amount of the scrap charged in the first preheating chamber by the first remaining amount measuring unit does not exist after the third step, , The first retractable cover is opened to charge the scrap into the first preheating chamber, and after the sixth step, the residual amount of the scrap charged into the second preheating chamber by the second remaining amount measuring section does not exist The first step is started and the scrap is charged into the second preheating chamber by opening the second retractable cover.

In the third and fourth objects of the present invention, the third step includes supplying oxidant and fuel to the second preheating combustor through the second supply pipe, Wherein the main exhaust gas flowing into the first preheating chamber and the exhaust gas from the second preheating chamber introduced into the first preheating chamber in the second and third steps are supplied to the first preheating combustor through the supply pipe, And the main exhaust gas flowing into the second preheating chamber in the fifth and sixth steps and the exhaust gas from the first preheating chamber are exhausted through the second exhaust pipe.

In the third and fourth objects of the present invention, there is provided an exhaust gas purifying apparatus comprising: a supply pipe connected to a preheating combustor, which is a preheating combustion mode; an exhaust pipe in a preheating chamber in a charge preheating mode, Further comprising the step of heat-exchanging the oxidizing agent and the fuel supplied to the preheating combustor, which is a preheating combustion mode, with each other.

A fifth object of the present invention is to provide an electric arc furnace which comprises a housing having an inner space, a partition wall partitioning the upper space of the inner space of the housing into at least one first preheating chamber and at least one second preheating chamber, Wherein the first preheating chamber is operated in a charging preheat mode when the first preheating chamber is in the preheating combustion mode, and the second preheating chamber is operated in the charging preheating mode, Wherein the first preheating chamber is operated in a preheating combustion mode when the first preheating chamber is in the charging preheat mode, the first preheating chamber comprises a first air permeable finger charged with scrap in the inner space and opening and closing the lower end, And a second preheating combustor for preheating the charged scrap, wherein the second preheating chamber comprises a second air permeable finger charged with scrap in the inner space and opening / closing the lower end, A scraper preheating device having a second preheating combustor; A scraper preheating device installed on one side of the scraping scraper, and a scrap preheated by the preheating device into the scraper; An electrode for arc generation for dissolving scrap; And a carbon sprayer for reducing the oxidized scrap. The present invention can be accomplished as an electric arc furnace equipped with a switching scrap preheater.

A sixth object of the present invention is to provide an electric arc furnace comprising at least one first preheating chamber having a first air-permeable finger charged with scrap in an inner space and opening and closing a lower end thereof, and a first preheating combustor for preheating charged scrap, And at least one second preheating chamber having a second air permeable finger for opening and closing the lower end portion and a second preheating combustor for preheating the charged scrap, the scrap being charged into the inner space, wherein the first preheating chamber is preheated Wherein the second preheating chamber is operated in a preheating combustion mode when the second preheating chamber is operated in a charging preheating mode and the first preheating chamber is in a charging preheating mode, A main body in which a thread is installed on one side of the upper part, the second preheating chamber is installed on the other side of the upper end, and scrap preheated by the preheating device is injected into the main body; An electrode for arc generation for dissolving scrap; And a carbon sprayer for reducing the oxidized scrap. The present invention can be accomplished as an electric arc furnace equipped with a switching scrap preheater.

According to an embodiment of the present invention, there is an effect of reducing the consumption of electric energy for arc generation required for melting by preheating the scrap at a high temperature, and eliminating odors generated during preheating.

The exhaust gas discharged from the first preheater (or the second preheater) of the plurality of steel scrap preheaters, which are alternately operated and each having a separate auxiliary combustor, passes through the high temperature atmosphere inside the electric arc furnace according to the installation method of the preheater, (Or first pre-heater) or the front end of the pre-heater at the lower end of the pre-heater, so that the high-temperature flue gas generated from the electric arc furnace is unreacted at the inlet of the second pre- The secondary combustion of chemical energy leads to an increase in flue-gas temperature, secondary scrubbing, and high-temperature preheating of steel scrap.

In addition, the sensible heat of the final flue-gas passing through the iron scrap preheater is utilized in addition to the combustor for the preheater and the auxiliary fuel for the secondary combustion and the oxidizer for the unreacted chemical energy recovery to improve the combustion efficiency (combustion control) The supply amount of each of the auxiliary heat sources required for the preheater, the unreacted chemical energy secondary combustion device, and the main body of the electric arc furnace can be actively and freely interlocked and adjustable according to the electric furnace operating conditions.

In particular, when the heat source required for a plurality of preheaters is supplied, the excess fuel is burned to control the amount of carbon monoxide and soot generated in the combustion products to actively suppress the surface oxidation of the iron scrap during preheating, So that it has an effect of reducing the amount of carbon blowing required in the process of dissolving / reducing the iron scrap by electric arc after charging it into the electric arc furnace main body.

In addition, since the electric arc furnace body can be sealed, cooling of the inside of the electric arc furnace due to the opening of the electric arc furnace to prevent the scrap iron from being charged can be prevented, thereby reducing the thermochemical energy and electric energy consumption.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be appreciated by those skilled in the art that various other modifications and variations can be made without departing from the spirit and scope of the invention, All fall within the scope of the appended claims.

1 is a cross-sectional view schematically showing the construction of a conventional electric arc furnace,
FIG. 2 is a view showing the construction of an electric arc furnace equipped with an alternating-type scrap preheating apparatus for an electric arc furnace according to a first embodiment of the present invention;
FIG. 3A is a view showing the construction of an electric arc furnace equipped with a switching scraper preheating device for an electric arc furnace in which a first preheating chamber is operated in a charging preheating mode and a second preheating chamber is operated in a preheating combustion mode according to a first embodiment of the present invention;
FIG. 3B is a view showing the construction of an electric arc furnace equipped with a switching scraper preheating device for an electric arc furnace in which a second preheating chamber is operated in a charging preheating mode and a first preheating chamber is operated in a preheating combustion mode according to a first embodiment of the present invention;
FIG. 4 is a view showing the construction of an electric arc furnace equipped with an alternating-type scrap preheating apparatus for an electric arc furnace according to a second embodiment of the present invention;
FIG. 5A is a view showing the construction of an electric arc furnace equipped with a switching scraper preheating device for an electric arc furnace in which a first preheating chamber is operated in a charging preheating mode and a second preheating chamber is operated in a preheating combustion mode according to a second embodiment of the present invention;
FIG. 5B is a view showing the construction of an electric arc furnace having a scraper preheating apparatus for an electric arc furnace in which a second preheating chamber is operated in a charging preheating mode and a first preheating chamber is operated in a preheating combustion mode according to a second embodiment of the present invention;
FIG. 6 is a front sectional view of an electric arc furnace equipped with an alternating-type scrap preheating apparatus for an electric arc furnace according to a second embodiment of the present invention,
FIG. 7 is a plan view of an electric arc furnace equipped with an alternating-type scrap preheating apparatus for an electric arc furnace according to a second embodiment of the present invention,
FIG. 8 is a side cross-sectional view of an electric arc furnace having an alternating scrap preheating apparatus for an electric arc furnace according to a second embodiment of the present invention,
9A is a cross-sectional view of an alternating scrap preheating apparatus for an electric arc furnace in which a first preheating chamber is operated in a preheating combustion mode and a second preheating chamber is operated in a charging preheating mode according to a second embodiment of the present invention,
9B is a cross-sectional view of an alternating scrap preheating apparatus for an electric arc furnace in which a second preheating chamber is operated in a preheating combustion mode and a first preheating chamber is operated in a charging preheating mode according to a second embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings. Throughout the specification, when a part is connected to another part, it includes not only a case where it is directly connected but also a case where the other part is indirectly connected with another part in between. In addition, the inclusion of an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

≪ Embodiment 1 >

Hereinafter, the structure and function of an electric arc furnace equipped with the intergranular scrap preheater 100 for an electric arc furnace according to the first embodiment of the present invention will be described. 2 is a schematic view of an electric arc furnace equipped with an alternating-type scrap preheater 100 for an electric arc furnace according to a first embodiment of the present invention. The iron scrap preheater 100 according to an embodiment of the present invention is provided with at least one electric arc furnace body, and is configured to allow gas flow with the interior of the electric arc furnace body. FIG. 2 illustrates one embodiment of the present invention, and the first preheating chamber 110 and the second preheating chamber 120 may be composed of a plurality of.

2, the intergranular scrap preheater 100 according to the first embodiment of the present invention includes a first preheating chamber 110 and a second preheating chamber 120, Mode and the preheat combustion mode are operated alternately with each other.

As shown in FIG. 2, the first preheating chamber 110 according to the first embodiment of the present invention includes a first air-permeable finger which is provided on one side of the upper end of the main body and is charged with scrap in the inner space, And a first preheating combustor 113 for preheating the charged scrap.

As shown in FIG. 2, the second preheating chamber 120 according to the first embodiment of the present invention is provided on the other side of the upper end of the main body. The scraper is filled in the inner space, and the second air- And a second preheating combustor 123 for preheating the charged scrap.

The scraper preheating apparatus 100 according to the first embodiment of the present invention operates in such a manner that the first preheating chamber 110 and the second preheating chamber 120 alternate between the charging preheat mode and the preheating combustion mode. That is, when the first preheating chamber 110 is in the preheating combustion mode, the second preheating chamber 120 operates in the charge preheating mode, and when the first preheating chamber 110 is in the charging preheating mode, Is operated in the preheat combustion mode.

More specifically, when the first preheating chamber 110 or the second preheating chamber 120 is operated in the preheating combustion mode, the breathable fingers of the preheating chamber, which is the preheating combustion mode, are closed, The preheating combustor is operated to preheat the scrap charged in the internal space, and the preheating chamber exhaust gas generated in the preheating combustion mode, which is the preheating combustion mode, flows into the preheating chamber, which is the charging preheating mode, through the inside of the main body, and is exhausted.

When the first preheating chamber 110 or the second preheating chamber 120 is operated in the charging preheating mode, the breathable fingers of the preheating chamber, which is the charging preheating mode, are opened and charged into the preheating chamber interior space Scrap is injected into the main body, and the exhaust gas in the main body flows into the preheating chamber which is the charging and preheating mode and is exhausted. In this process, the iron scrap charged in the preheating chamber, which is a preheating combustion mode, is preheated by the preheating combustor, and the iron scrap charged in the preheating chamber, which is a charging preheating mode, is also preheated by the main body flue gas and introduced into the main body.

In addition, a secondary combustion device may be provided in the first preheating chamber 110 and the inner lower end of the second preheating chamber 120. With such a secondary combustion device, the exhaust gas in the main body flowing into the preheating chamber, which is a charging and preheating mode, is burned to convert unreacted chemical energy of the main exhaust gas into heat energy.

As shown in FIG. 2, scrap is charged into the upper ends of the first preheating chamber 110 and the second preheating chamber 120 of the alternating scrap preheater 100 according to the first embodiment of the present invention, And the opening / closing covers 115 and 125 for opening and closing the door. Each of the first preheating chamber 110 and the second preheating chamber 120 is provided with a remaining amount measuring unit for measuring the residual amount of scrap charged therein so that the remaining amount of scrap charged into the inside of the apparatus, In the absence of the mode, as described later, the mode can be alternated and the opening and closing cover can be opened and the scrap can be put into the preheating chamber.

2, the alternating scrap preheater 100 according to the first embodiment of the present invention is provided with a first preheating combustor 113, which is a preheat combustion mode, A supply pipe 111 and a second supply pipe for supplying oxidant and fuel to the second preheating combustor 123 which is a preheat combustion mode.

Therefore, the oxidizer and the fuel are injected into the preheating combustor through the supply pipe in the preheating combustion chamber in the preheating combustion mode, and the scrap in the preheating chamber, which is the preheating combustion mode, is preheated. The preheating combustor may use air or oxygen enriched air or oxygen as the oxidizer, and the oxidant and the fuel to be supplied are preheated and supplied by the heat exchanger 130, as will be described later.

2, the intergranular scrap preheating apparatus 100 according to the first embodiment of the present invention includes a first preheating chamber 110 provided in the first preheating chamber 110 and in a charging preheating mode, A main exhaust gas flowing into the second preheating chamber 120 provided in the second preheating chamber 120 and a preheating chamber exhaust gas introduced into the second preheating chamber 120, which is provided in the second preheating chamber 120, And a second exhaust pipe 124 through which exhaust gas is exhausted.

2, the intergranular scrap preheater 100 according to the first embodiment of the present invention includes a first supply pipe 111, a second supply pipe, an exhaust pipe (first exhaust pipe 114, And a heat exchanger 130 connected to the second exhaust pipe 124). The heat exchanger 130 is also connected to an oxidant supply pipe (not shown) and a fuel supply pipe (not shown).

Therefore, the exhaust gas exhausted through the exhaust pipe in the preheating chamber in the charging mode is supplied to the heat exchanger 130, and the oxidant and the fuel are supplied into the heat exchanger 130 through the oxidant supply pipe and the fuel supply pipe through other paths The oxidizer and the fuel are preheated in the heat exchanger 130 and the preheated oxidizer and the fuel are introduced into the preheating combustor in the preheat combustion chamber through the supply pipe. Meanwhile, the exhaust gas is discharged through the heat exchanger 130 through the exhaust fan.

Hereinafter, the preheating method and the operation method of the electric arc furnace of the intergranular scrap preheater 100 for an electric arc furnace according to the first embodiment of the present invention will be described. FIG. 3A is a schematic view illustrating an alternate scrap preheating apparatus 100 for an electric arc furnace in which a first preheating chamber 110 is operated in a charging preheating mode and a second preheating chamber 120 is operated in a preheating combustion mode according to a first embodiment of the present invention Fig. 2 is a block diagram of an electric arc furnace. FIG. 3B is a schematic view illustrating an alternate scrap preheater 100 for an electric arc furnace in which a second preheating chamber 120 is operated in a charging preheating mode and a first preheating chamber 110 is operated in a preheating combustion mode according to a first embodiment of the present invention. Fig. 2 is a block diagram of an electric arc furnace equipped with an electric arc furnace.

The second combustor 140 provided in the first preheating chamber 110 operated in the charging preheating mode is operated to cool the first preheating chamber 110, The unreacted chemical energy of the main flue gas which is to be introduced into the flue gas is converted into thermal energy.

That is, the first air-permeable finger is opened and the scrap charged in the first preheating chamber 110 is introduced into the main body. As shown in FIG. 3A, it can be seen that the exhaust gas in the main body flows into the first preheating chamber 110 and is exhausted through the first exhaust pipe 114. 3a and 3b show the flow path of the main exhaust gas and the dashed arrows show the flow path of the preheating chamber exhaust gas.

The second preheating combustor 123 provided in the second preheating chamber 120 is operated to preheat the scrap in the second preheating chamber 120 and the preheating chamber exhaust gas generated in the second preheating chamber 120 Is introduced into the first preheating chamber (110) through the main body and exhausted through the first exhaust pipe (114). Accordingly, the first preheating chamber 110 is operated in the charging preheating mode and the second preheating chamber 120 is operated in the preheating combustion mode.

In this process, the exhaust gas discharged through the first exhaust pipe 114 passes through the heat exchanger 130, and preheats the oxidant and the fuel to be supplied to the second preheating combustor 123 through the second supply pipe. Therefore, the preheated oxidizer and the fuel are introduced into the second preheating combustor 123.

This process may be continued for a specific period of time or until the residual amount of scrap in the first preheating chamber 110 is less than a predetermined amount. That is, the first residual amount measuring unit provided in the first preheating chamber 110 measures the amount of scrap remaining in the first preheating chamber 110 in real time, and the residual amount of scrap in the first preheating chamber 110 is set to a predetermined amount The control unit changes modes of the first preheating chamber 110 and the second preheating chamber 120 to each other. That is, the second preheating chamber 120 is operated in the charging preheating mode, and the first preheating chamber 110 is operated in the preheating combustion mode.

Specifically, the operation of the second preheating combustor 123 is stopped, the first air-permeable finger 112 is closed to close the first preheating chamber 110 and the second air-permeable finger 122 is opened, The scrap charged into the main body 120 is put into the main body. In this process, the first openable cover 115 provided at the upper end of the first preheating chamber 110 is opened and the scrap is charged into the first preheating chamber 110.

The second gas permeable finger 122 of the second preheating chamber 120 is opened and the exhaust gas in the main body flows into the second preheating chamber 120 and flows through the second exhaust pipe 124 It can be understood that it is exhausted.

When the scrap is charged into the first preheating chamber 110, the first preheating combustor 113 provided in the first preheating chamber 110 is operated to preheat the scrap in the first preheating chamber 110 The preheating chamber exhaust gas generated in the first preheating chamber 110 flows into the second preheating chamber 120 through the main body and is exhausted through the second exhaust pipe 124. Accordingly, the first preheating chamber 110 is operated in the preheating combustion mode in the second preheating chamber 120 in the charge preheating mode.

In this process, the exhaust gas discharged through the second exhaust pipe 124 passes through the heat exchanger 130 and is supplied to the first preheating combustor 113 through the first supply pipe 111 and the preheated fuel . Therefore, the preheated oxidizer and the fuel are introduced into the first preheating combustor 113.

This process may be continued for a specific period of time or until the remaining amount of scrap in the second preheating chamber 120 is less than a predetermined amount. That is, the second residual amount measuring unit provided in the second preheating chamber 120 measures the amount of scrap remaining in the second preheating chamber 120 in real time, and the residual amount of scrap in the second preheating chamber 120 is set to a predetermined amount The control unit changes modes of the first preheating chamber 110 and the second preheating chamber 120 to each other. That is, the first preheating chamber 110 is operated again in the charging preheating mode, and the second preheating chamber 120 is operated in the preheating combustion mode. As this process is continuously repeated, the alternating scrap preheating apparatus 100 according to the first embodiment of the present invention is operated.

≪ Embodiment 2 >

Hereinafter, the structure and function of an electric arc furnace equipped with the alternating scrap preheater 100 for an electric arc furnace according to a second embodiment of the present invention will be described. 4 is a schematic view of an electric arc furnace equipped with an alternating-type scrap preheating apparatus 100 for an electric arc furnace according to a second embodiment of the present invention. 5A is a schematic view illustrating an alternate scrap preheater 100 for an electric arc furnace in which a first preheating chamber 110 is operated in a charging preheating mode and a second preheating chamber 120 is operated in a preheating combustion mode according to a second embodiment of the present invention, Fig. 2 is a block diagram of an electric arc furnace equipped with an electric arc furnace. 5B is a schematic view of a scraper preheater 100 for an electric arc furnace in which a second preheating chamber 120 is operated in a charging preheating mode and a first preheating chamber 110 is operated in a preheating combustion mode according to a second embodiment of the present invention, Fig. 2 is a block diagram of an electric arc furnace equipped with an electric arc furnace.

6 is a front sectional view of an electric arc furnace equipped with an alternating-type scrap preheating apparatus 100 for an electric arc furnace according to a second embodiment of the present invention, and Fig. 7 is a cross- 1 is a plan view of an electric arc furnace equipped with an alternating scrap preheating apparatus 100 for an electric arc furnace. 8 is a side cross-sectional view of an electric arc furnace equipped with an alternating scrap preheater 100 for an electric arc furnace according to a second embodiment of the present invention.

The scraper scraper preheater 100 according to the second embodiment of the present invention differs from the scraper scraper according to the second embodiment in that a partition wall 102 is provided in a single preheating chamber 110 and a second preheating chamber And the lower end internal space of the preheating device 100 is constituted by a buffer unit 103. The buffer unit 103 is provided with a secondary combustion apparatus and scrap charged in the buffer unit 103, The input means 104 for continuously inputting the input signal is provided.

4, 5A, 5B, 6, 7 and 8, the housing 101 according to the second embodiment of the present invention is provided at one side of the top of the acro body and has an internal space. The housing 101 is provided with a partition 102 dividing the upper space of the inner space of the housing 101 into at least one first preheating chamber 110 and at least one second preheating chamber 120 .

As shown in FIGS. 5, 6 and 8, it can be seen that the buffer unit 103 is located in the lower end internal space of the housing 101. 8, the loading means 104 corresponds to a structure for loading the scrap introduced into the buffer unit 103 into the main body.

In the second embodiment of the present invention, the first preheating chamber 110 and the second preheating chamber 120 are operated alternately in the preheating combustion mode and the charge preheating mode. That is, when the first preheating chamber 110 is in the preheating combustion mode, the second preheating chamber 120 is operated in the charge preheating mode, and when the first preheating chamber 110 is in the charge preheating mode, The preheating chamber 110 is operated in the preheating combustion mode.

In addition, the first preheating chamber 110 according to the second embodiment of the present invention includes a first air-permeable finger charged with scrap in the inner space and opening / closing the lower end thereof, and a first preheating combustor 113). The second preheating chamber 120 also includes a second air-permeable finger charged with scrap in the inner space and opening and closing the lower end thereof, and a second preheating combustor 123 for preheating the charged scrap .

5A, when the first preheating chamber 110 is operated in the charging preheating mode and the second preheating chamber 120 is operated in the preheating combustion mode, the first preheating chamber 110, which is the charging preheating mode, The first air-permeable finger 112 of the first air-permeable finger 112 is opened so that the scrap charged in the internal space of the first preheating chamber 110 flows into the buffer portion 103 and is supplied to the buffer portion 103 by the input means 104 The scrap is continuously introduced into the main body, and the exhaust gas in the main body flows into the first preheating chamber 110, which is a charging preheating mode, and is exhausted through the first exhaust pipe 114.

5A, the second air-permeable fingers 122 of the second preheating chamber 120, which is the preheating combustion mode, are closed, and the second preheating combustor 123 in the second preheating chamber 120 is closed, The scrap charged in the inner space is preheated and burned, and the exhaust gas of the second preheating chamber 120 flows into the first preheating chamber 110, which is a charging preheating mode.

5B, when the first preheating chamber 110 is operated in the preheating combustion mode and the second preheating chamber 120 is operated in the charge preheating mode, the second preheating chamber The second air permeable fingers 122 of the first preheating chamber 120 are opened so that the scrap charged into the internal space of the second preheating chamber 120 flows into the buffer unit 103 and is supplied to the buffer unit 103 The charged scrap is continuously introduced into the main body, and the exhaust gas in the main body flows into the second preheating chamber 120, which is a charging preheat mode, and is exhausted through the second exhaust pipe 124.

5B, the first air-permeable fingers 112 of the first preheating chamber 110, which is the preheating combustion mode, are closed, and the first preheating combustor 113 in the first preheating chamber 110 is closed, The scrap charged in the inner space is preheated and burned, and the exhaust gas of the first preheating chamber 110 flows into the second preheating chamber 120, which is a charging preheating mode.

The unreacted chemical energy of the exhaust gas flowing into the preheating chamber, which is a charging preheating mode, is converted into thermal energy by the secondary combustion device provided in the buffer unit 103 and flows into the preheating chamber in the charging preheating mode.

As shown in FIGS. 4, 5A and 5B, openable and closable covers 115 and 125 provided at the upper ends of the first preheating chamber 110 and the second preheating chamber 120 for loading scrap, .

Each of the first preheating chamber 110 and the second preheating chamber 120 is provided with a remaining amount measuring unit for measuring the residual amount of scrap charged therein so that the remaining amount of scrap charged into the inside of the apparatus, When the mode is changed, the scrap can be put into the preheating chamber by opening the opening type cover at the same time as the mode is alternated.

4, 5A and 5B, in the alternating scrap preheater 100 according to the second embodiment of the present invention, the oxidizing agent and the oxidizing agent are supplied to the first preheating combustor 113 side, which is the preheating combustion mode, A first supply pipe 111 for supplying fuel and a second supply pipe for supplying oxidant and fuel to the second preheating combustor 123 which is a preheat combustion mode.

Therefore, the oxidizer and the fuel are injected into the preheating combustor through the supply pipe in the preheating combustion chamber in the preheating combustion mode, and the scrap in the preheating chamber, which is the preheating combustion mode, is preheated. The preheating combustor may use air or oxygen enriched air or oxygen as the oxidizer, and the oxidant and the fuel to be supplied are preheated and supplied by the heat exchanger 130, as will be described later.

4, 5A and 5B, the intergranular scrap preheater 100 according to the second embodiment of the present invention is provided in the first preheating chamber 110, A first exhaust pipe 114 through which the main exhaust gas flowing into the first preheating chamber 110 and the preheater exhaust gas are exhausted and a second exhaust pipe 114 provided in the second preheating chamber 120 and flowing into the second preheating chamber 120, And a second exhaust pipe (124) through which the main exhaust gas and the preheating chamber exhaust gas are exhausted.

4, 5A and 5B, the scraped scrap preheater 100 according to the first embodiment of the present invention includes a first supply pipe 111, a second supply pipe, an exhaust pipe (first pipe The exhaust pipe 114, and the second exhaust pipe 124), as shown in FIG. The heat exchanger 130 is also connected to an oxidant supply pipe (not shown) and a fuel supply pipe (not shown).

Therefore, the exhaust gas exhausted through the exhaust pipe in the preheating chamber in the charging mode is supplied to the heat exchanger 130, and the oxidant and the fuel are supplied into the heat exchanger 130 through the oxidant supply pipe and the fuel supply pipe through other paths The oxidizer and the fuel are preheated in the heat exchanger 130 and the preheated oxidizer and the fuel are introduced into the preheating combustor in the preheat combustion chamber through the supply pipe. Meanwhile, the exhaust gas is discharged through the heat exchanger 130 through the exhaust fan.

Hereinafter, the preheating method using the intergranular scrap preheating apparatus 100 for an electric arc furnace according to the second embodiment and the operation method of the electric arc furnace will be described. 9A is a schematic view of a scraper preheater 100 for an electric arc furnace in which a first preheating chamber 110 is operated in a preheating combustion mode and a second preheating chamber 120 is operated in a charging preheat mode according to a second embodiment of the present invention. Fig. 9B is a schematic view showing an alternate scrap preheating apparatus 100 for an electric arc furnace in which a second preheating chamber 120 is operated in a preheating combustion mode and a first preheating chamber 110 is operated in a charging preheat mode according to a second embodiment of the present invention. ). ≪ / RTI >

First, the scrap charged in the main body is burnt to generate exhaust gas, and the secondary combustion apparatus 140 provided in the buffer unit 103 is operated to flow into the second preheating chamber 120, It converts chemical energy into thermal energy.

As shown in FIG. 9A, the second air-permeable fingers are opened, and the scrap charged in the second preheating chamber 120 is introduced into the buffer unit 103. The scrap introduced into the buffer unit 103 is continuously introduced into the main body by the input means 104. [ 9A, the exhaust gas in the main body flows into the buffer unit 103, unreacted chemical energy is converted into thermal energy by the secondary combustion apparatus, and then flows into the second preheating chamber 120 And exhausted through the second exhaust pipe 124.

The first preheating combustor 113 provided in the first preheating chamber 110 is operated to preheat the scraps in the first preheating chamber 110. The preheating chamber exhaust gas generated in the first preheating chamber 110 The exhaust gas flows into the second preheating chamber 120 through the buffer unit 103 and the main body, and is exhausted through the second exhaust pipe 124. Therefore, the first preheating chamber 110 is operated in the preheating combustion mode in the second preheating chamber 120 in the charging preheating mode.

5B, the exhaust gas exhausted through the second exhaust pipe 124 passes through the heat exchanger 130 and flows through the first supply pipe 111 to the first preheating combustor 113 The oxidizing agent and the fuel to be injected are preheated. Therefore, the preheated oxidizer and the fuel are introduced into the first preheating combustor 113.

This process may be continued for a specific period of time or until the remaining amount of scrap in the second preheating chamber 120 is less than a predetermined amount. That is, the second residual amount measuring unit provided in the second preheating chamber 120 measures the amount of scrap remaining in the second preheating chamber 120 in real time, and the residual amount of scrap in the second preheating chamber 120 is set to a predetermined amount The control unit changes modes of the first preheating chamber 110 and the second preheating chamber 120 to each other. That is, the second preheating chamber 120 is operated in the preheating combustion mode, and the first preheating chamber 110 is operated in the charging preheating mode.

Specifically, as shown in FIG. 9B, the operation of the first preheating combustor 113 is stopped, the second air-permeable finger is closed to close the second preheating chamber 120, and the first air-permeable finger 112 is opened So that the scrap charged in the first preheating chamber 110 is put into the buffer unit 103. Also, in this process, the second openable cover 125 provided at the upper end of the second preheating chamber 120 is opened and the scrap is charged into the second preheating chamber 120.

The first air permeable finger 112 of the first preheating chamber 110 is opened and the exhaust gas in the main body flows into the first preheating chamber 110 and flows through the first exhaust pipe 114 It can be understood that it is exhausted.

When the scrap is charged into the second preheating chamber 120, the second preheating combustor 123 provided in the second preheating chamber 120 is operated to preheat the scrap in the second preheating chamber 120 The preheating chamber exhaust gas generated in the second preheating chamber 120 flows into the first preheating chamber 110 through the buffer unit 103 and the main body and is exhausted through the first exhaust pipe 114. Accordingly, the first preheating chamber 110 is operated in the charging preheating mode and the second preheating chamber 120 is operated in the preheating combustion mode.

In this process, the exhaust gas discharged through the first exhaust pipe 114 passes through the heat exchanger 130, and preheats the oxidant and the fuel to be supplied to the second preheating combustor 123 through the second supply pipe. Therefore, the preheated oxidizer and the fuel are introduced into the second preheating combustor 123.

This process may be continued for a specific period of time or until the residual amount of scrap in the first preheating chamber 110 is less than a predetermined amount. That is, the first residual amount measuring unit provided in the first preheating chamber 110 measures the amount of scrap remaining in the first preheating chamber 110 in real time, and the residual amount of scrap in the first preheating chamber 110 is set to a predetermined amount The control unit changes modes of the first preheating chamber 110 and the second preheating chamber 120 to each other. That is, the first preheating chamber 110 is operated again in the preheating combustion mode, and the second preheating chamber 120 is operated in the charge preheating mode. As this process is continuously repeated, the alternating scrap preheating apparatus 100 according to the second embodiment of the present invention is operated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. It is to be understood that such modified embodiments are within the scope of protection of the present invention as defined by the appended claims.

1: Electrode for arc generation
2: Carbon sprayer for reduction of molten iron
3: Oxygen injector for secondary combustion
4: Oxygen burner for heating additional steel scrap
5: Iron scrap preheater
6: Unreacted secondary energy / heat exchanger for chemical energy recovery and odor removal
7: Bag filter for dust removal
8: Exhaust fan
9: Fused iron
10: electric arc main body
11: scrap
100: Alternating scrap preheating device for electric arc furnace
101: Housing
102:
103: buffer unit
104: input means
110: First preheating chamber
111: first supply pipe
112: first breathable finger
113: First preheating combustor
114: First exhaust pipe
115: First retractable cover
120: Second preheating chamber
121: first supply pipe
122: first breathable finger
123: First preheating combustor
124: first exhaust pipe
125: First retractable cover
130: Heat exchanger
140: Secondary combustion device

Claims (21)

An iron scrap preheater comprising at least one electric arc furnace body and gas flowable inside the furnace body,
A housing provided at one side of the main body and having an inner space;
A partition wall partitioning the upper part of the inner space of the housing into at least one first preheating chamber and at least one second preheating chamber;
A buffer unit located at a lower end of the inner space of the housing; And
And input means for loading the scrap introduced into the buffer portion into the main body,
Wherein when the first preheating chamber is in the preheating combustion mode, the second preheating chamber is operated in the charging preheating mode, and when the first preheating chamber is in the charging preheating mode, the first preheating chamber is operated in the preheating combustion mode,
Wherein the first preheating chamber includes a first air permeable finger charged with scrap in an inner space and opening and closing a lower end thereof, and a first preheating combustor for preheating charged scrap,
Wherein the second preheating chamber comprises a second air-permeable finger charged with scrap in an inner space and opening and closing a lower end thereof, and a second preheating combustor for preheating charged scrap, Device.
The method according to claim 1,
When the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode,
The breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated to preheat the scrap charged in the inner space and the preheating chamber exhaust gas flows into the preheating chamber in the charging preheating mode,
When the first preheating chamber or the second preheating chamber is operated in the charging preheating mode,
Wherein the breathable fingers of the preheating chamber in the charging and preheating mode are opened so that the scrap charged in the space of the preheating chamber flows into the buffer portion and the exhaust gas in the main body flows into the preheating chamber which is the charging preheating mode and is exhausted. Scrap preheating device.
3. The method of claim 2,
Further comprising a secondary combustion device provided in the buffer unit for converting unreacted chemical energy of the exhaust gas into a thermal energy flowing into the preheating chamber which is a charging preheating mode into thermal energy, .
An iron scrap preheater comprising at least one electric arc furnace body and gas flowable inside the furnace body,
At least one first preheating chamber provided at one side of the main body and having a first air permeable finger charged with scrap in an inner space and opening and closing a lower end portion and a first preheating combustor for preheating charged scrap; And
And at least one second preheating chamber provided at the other side of the main body and having a second air-permeable finger charged with scrap in the inner space and opening and closing the lower end portion, and a second preheating combustor for preheating the charged scrap,
Wherein when the first preheating chamber is in a preheating combustion mode, the second preheating chamber is operated in a charging preheating mode, and when the first preheating chamber is in a charging preheating mode, the first preheating chamber is operated in a preheating combustion mode For the electric arc furnace.
5. The method of claim 4,
When the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode,
The breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated to preheat the scrap charged in the inner space and the preheating chamber exhaust gas flows into the preheating chamber,
When the first preheating chamber or the second preheating chamber is operated in the charging preheating mode,
Wherein the breathable fingers of the preheating chamber in the charging and preheating mode are opened so that the scrap charged into the space of the preheating chamber flows into the main body and the exhaust gas in the main body flows into the preheating chamber which is the charging preheating mode and is exhausted. Scrap preheating device.
6. The method of claim 5,
And a secondary combustion device provided at an inner lower end of the first preheating chamber and the second preheating chamber for converting the unreacted chemical energy of the exhaust gas in the main body into the preheating chamber, For the electric arc furnace.
The method according to claim 1 or 4,
Further comprising a retractable cover provided on each of the upper ends of the first preheating chamber and the second preheating chamber for loading scrap.
The method according to claim 1 or 4,
A first supply pipe for supplying the oxidant and the fuel to the first preheating combustor side in the preheat combustion mode, a second supply pipe for supplying the oxidant and the fuel to the second preheat combustion combustor in the preheat combustion mode, A main exhaust gas flowing into the first preheating mode and a first exhaust pipe exhausting the preheating chamber exhaust gas, a main exhaust gas flowing into the second preheating chamber provided in the second preheating chamber, and a preheating chamber exhausted from the preheating chamber exhaust gas And a second exhaust pipe.
9. The method of claim 8,
A supply pipe connected to the preheating combustor, which is a preheating combustion mode, and an exhaust pipe connected to the exhaust pipe of the preheating chamber, which is a preheating preheat mode, through an exhaust pipe of the preheating chamber, Further comprising a heat exchanger for exchanging heat with the flue gas.
A scrap preheating method using an alternating scrap preheating apparatus for an electric arc furnace in which an internal space is partitioned into a first preheating chamber and a second preheating chamber by partition walls and a buffer unit is provided in a lower internal space,
A first step in which the first preheating chamber is opened by the first air permeable finger and the scrap charged in the first preheating chamber is introduced into the buffer part;
A second step in which flue gas in the main body flows into the buffer unit and the first preheating chamber;
The second preheating combustor is operated to preheat the scrap in the second preheating chamber and the second preheating chamber exhaust gas flows into the first preheating chamber via the buffer portion so that the first preheating chamber is in the charge preheating mode and the second preheating chamber is preheated A third step of operating in a mode;
After the lapse of a predetermined time, the operation of the second preheating combustor is stopped, the first preheating chamber is closed by the first breathable fingers and the second preheating chamber is opened by the second breathable fingers, A fourth step in which the scrap is injected into the buffer unit;
A fifth step in which flue gas in the main body flows into the buffer unit and the second preheating chamber;
The first preheating combustor is operated to preheat the scrap in the first preheating chamber and the first preheating chamber exhaust gas flows into the second preheating chamber through the buffer portion and the main body so that the first preheating chamber is in the preheating combustion mode, Actually, the sixth step is operated in the charging and warming mode; And
And repeating the first, second, third, fourth, fifth, and sixth steps. The method of preheating scrap using an alternating scrap preheating apparatus for an electric arc furnace.
11. The method of claim 10,
Further comprising the step of converting the unreacted chemical energy of the main exhaust gas flowing into the preheating chamber, which is a charging and preheating mode, into thermal energy by the secondary combustion device provided in the buffer unit, to heat energy, Scrap preheating method using.
A scrap preheating method using an alternating scrap preheating apparatus for an electric arc furnace having a first preheating chamber provided on one side of an electric arc furnace body and a second preheating chamber provided on the other side,
A first step in which a first preheating chamber is opened by a first breathable finger and scrap charged in the first preheating chamber is injected into a main body;
A second step in which flue gas in the main body flows into the first preheating chamber;
The second preheating combustor is operated to preheat the scrap in the second preheating chamber and the second preheating chamber exhaust gas flows into the first preheating chamber through the main body so that the first preheating chamber is in the charge preheating mode and the second preheating chamber is preheated A third step of operating in a mode;
After the lapse of a predetermined time, the operation of the second preheating combustor is stopped, the first preheating chamber is closed by the first breathable fingers and the second preheating chamber is opened by the second breathable fingers, A fourth step of putting scrap into the main body;
A fifth step in which flue gas in the main body flows into the second preheating chamber;
The first preheating combustor is operated to preheat the scrap in the first preheating chamber and the first preheating chamber exhaust gas flows into the second preheating chamber through the main body so that the first preheating chamber is in the preheating combustion mode and the second preheating chamber is the preheating preheating A sixth step of operating in a mode; And
And repeating the first, second, third, fourth, fifth, and sixth steps. The method of preheating scrap using an alternating scrap preheating apparatus for an electric arc furnace.
13. The method of claim 12,
The second step may further include the step of converting unreacted chemical energy of the main exhaust gas flowing into the first preheating chamber into heat energy by the secondary combustion device provided at the lower end of the first preheating chamber,
Wherein the fifth step further comprises the step of converting the unreacted chemical energy of the main exhaust gas flowing into the second preheating chamber into the thermal energy by the secondary combustion device provided at the lower end of the second preheating chamber Scrap preheating method using alternating scrap preheater.
13. The method according to claim 10 or 12,
Measuring a remaining amount of scrap charged in the first preheating chamber by a first remaining amount measuring unit provided in the first preheating chamber; And
Wherein the second residual amount measuring unit provided in the second preheating chamber further comprises measuring a residual amount of scrap charged in the second preheating chamber.
15. The method of claim 14,
And if it is determined by the first residual amount measuring unit that the residual amount of scrap charged in the first preheating chamber does not exist after the third step, the fourth step is started, and the first retractable cover is opened, 1 The scrap is charged into the preheating chamber,
The first step is started and the second retractable cover is opened so that the residual amount of the scrap charged in the second preheating chamber does not exist by the second residual amount measuring unit after the sixth step, 2. A scrap preheating method using an alternating scrap preheating apparatus for an electric arc furnace, characterized in that scrap is charged into the preheating chamber.
13. The method according to claim 10 or 12,
Wherein the third step includes supplying oxidant and fuel to the second preheating combustor through a second supply pipe,
The sixth step includes supplying oxidant and fuel to the first preheating combustor through the first supply pipe,
The main flue gas and the second preheating chamber flue gas introduced into the first preheating chamber in the second and third steps are exhausted through the first exhaust pipe, Wherein the flue gas and the first preheating chamber exhaust gas are exhausted through the second exhaust pipe.
17. The method of claim 16,
An exhaust gas exhausted through an exhaust pipe of the preheating chamber in the charge preheating mode by a supply pipe connected to a preheating combustor in a preheat combustion mode and a discharge pipe of a preheat chamber in a charge preheating mode, and a preheating combustor Further comprising the step of heat-exchanging the supplied oxidizing agent and fuel with each other.
In an electric arc furnace,
A housing having an inner space, a partition wall partitioning the upper space of the inner space of the housing into at least one first preheating chamber and at least one second preheating chamber, a buffer part located at the lower end of the inner space of the housing, Wherein when the first preheating chamber is in the preheating combustion mode, the second preheating chamber is operated in the charge preheating mode, and when the first preheating chamber is in the charging preheat mode, The first preheating chamber is operated in a preheating combustion mode, and the first preheating chamber includes a first air-permeable finger charged with scrap in the inner space and opening / closing the lower end portion, and a first preheating combustor for preheating charged scrap And the second preheating chamber includes a second air-permeable finger charged with scrap in the inner space and opening / closing the lower end portion, and a second preheating combustor for preheating the charged scrap Type scrap preheating apparatus;
A scraper preheating device installed on one side of the scraping scraper, and a scrap preheated by the preheating device into the scraper;
An electrode for arc generation for dissolving scrap; and
And a carbon sprayer for reducing the oxidized scrap. ≪ Desc / Clms Page number 19 >
20. The method of claim 19,
When the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode,
The breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated to preheat the scrap charged in the inner space and the preheating chamber exhaust gas flows into the preheating chamber in the charging preheating mode,
When the first preheating chamber or the second preheating chamber is operated in the charging preheating mode,
Wherein the breathable fingers of the preheating chamber in the charging and preheating mode are opened so that the scrap charged into the space of the preheating chamber flows into the buffer portion and the exhaust gas in the main body flows into the preheating chamber which is the charging preheating mode and is exhausted. .
In an electric arc furnace,
A first preheating chamber having a first air permeable fingers for opening and closing a lower end portion and a first preheating combustor for preheating charged scrap, a scraper in an inner space, And a second preheating combustor for preheating the charged scrap, wherein when the first preheating chamber is in the preheating combustion mode, the second preheating chamber is provided with a preheating preheater Wherein the first preheating chamber is operated in a preheating combustion mode when the first preheating chamber is in the charging preheating mode;
A main body in which the first preheating chamber is installed on one side of the upper end, the second preheating chamber is installed on the other side of the upper end and scrap preheated by the preheating device is injected into the main body;
An electrode for arc generation for dissolving scrap; And
And a carbon sprayer for reducing the oxidized scrap. ≪ Desc / Clms Page number 19 >
21. The method of claim 20,
When the first preheating chamber or the second preheating chamber is operated in the preheating combustion mode,
The breathable fingers of the preheating chamber in the preheating combustion mode are closed and the preheating combustor in the preheating chamber is operated to preheat the scrap charged in the inner space and the preheating chamber exhaust gas flows into the preheating chamber,
When the first preheating chamber or the second preheating chamber is operated in the charging preheating mode,
Wherein the air-permeable fingers of the preheating chamber, which is a charging preheating mode, are opened so that the scrap charged into the preheating chamber flows into the main body, and the exhaust gas in the main body flows into the preheating chamber which is the charging preheating mode, .

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