KR19990066830A - Furnace Preheating Equipment - Google Patents

Abstract

The metal scrap is prevented from being sucked into the exhaust gas duct of the furnace top preheater, and even if a part of the metal scrap is sucked, the metal scrap is captured at the uppermost side of the exhaust gas treatment device, so that the metal scrap is exhaust gas downstream. It does not accumulate in the duct or enter the deodorization tower or cooler or dust collector, thus maintaining a smooth flow of exhaust gas and also maintaining the function of the deodorization tower or cooler, or dust collector. To provide.

In the furnace top preheating apparatus which has a preheating apparatus equipped in the top of a furnace of a furnace, and the exhaust gas processing apparatus connected to the said preheating apparatus, two or more preheating chambers may be installed in the shaft equipped in the top of a furnace in the one or the up-down direction. The exhaust gas duct which has a damper was respectively connected to the shaft wall lower than the upper part of each shaft wall which forms each preheating chamber, and the lower part of the preheating chamber.

Description

Furnace Preheating Equipment

The present invention relates to furnace top preheating equipment. In the case of dissolving metal scrap in a furnace such as a burner furnace or an arc furnace, preheating of the metal scrap as a raw material with hot exhaust gas generated in the melting furnace is performed. Various apparatuses are used for preheating the metal scrap, but one of them includes a furnace top preheater. The furnace top preheater is a finger that can be opened and closed within the shaft installed at the furnace top of the furnace, and one or more preheating chambers are partitioned in the vertical direction. Preheated by exhaust gas. Since the exhaust gas after the preheating of the metal scrap is discharged from the furnace top preheater, an exhaust gas treatment device is connected to the furnace top preheater. The present invention relates to an improvement of a furnace top preheating facility comprising the above furnace top preheater and an exhaust gas treatment device connected thereto.

Conventionally, in the furnace top preheating apparatus in the furnace top preheating equipment, the exhaust gas duct connected to the upper part of the shaft wall which forms the uppermost preheating chamber is the exhaust gas after preheating the metal scrap loaded in the preheating chamber. There is a suction exhaust from the exhaust gas, or a suction exhaust from the exhaust gas duct connected to the upper part of the shaft wall forming the preheating chamber other than the uppermost stage. For example, one preheating chamber is partitioned by a finger that can be opened and closed within the shaft of the furnace top equipment, and an exhaust gas duct is connected to the upper part of the shaft wall forming the preheating chamber. The hot exhaust gas generated in the melting furnace is introduced into the preheating chamber to preheat the metal scrap loaded in the preheating chamber, and the exhaust gas after preheating is sucked and exhausted through the exhaust gas duct in the preheating chamber. Also, for example, two stages of preheating chambers are partitioned in the up and down direction by fingers that can be opened and closed in the shaft of the top of the equipment, and the upper and lower shaft walls from the preheating chambers of the lower and lower shaft walls form the preheating chambers. There is a bypass duct between them, and an exhaust gas duct is connected to the upper part of the shaft wall forming the preheating chamber at the lower end (Japanese Patent Laid-Open No. 8-54191, Japanese Patent Laid-Open No. 8-136163, Japanese Patent Laid-Open No. 9-257377). In the furnace top preheater, a part of the hot exhaust gas generated in the melting furnace is introduced into the lower preheating chamber, the metal scrap loaded in the lower preheating chamber is preheated, and the hot exhaust gas generated in the melting furnace is heated. The remaining part of the gas is introduced into the upper preheating chamber through the bypass duct to preheat the metal scrap loaded in the upper preheating chamber, and the exhaust gas after the preheating Suction is adapted to exhaust through the exhaust duct from the pre-heating chamber. However, in the conventional furnace top preheater, a part of the waste gas is fed into the exhaust gas duct when the metal scrap is put into the upper preheating chamber or when the metal scrap preheated in the upper preheating chamber is dropped into the lower preheating chamber. There is a problem of being sucked in and deposited in the exhaust gas duct. If metal scrap is deposited in the exhaust duct, it will interfere with the smooth flow of the exhaust gas through the exhaust duct.

On the other hand, as the exhaust gas treatment apparatus in the furnace top preheater as described above, a dust collector is connected to an exhaust gas duct for exhausting the exhaust gas after preheating by the furnace top preheater through a deodorizing tower or a cooler. However, such a conventional exhaust gas treatment device sucks a portion of the scrap into the exhaust gas duct when the metal scrap is put into the upper preheating chamber or when the metal scrap preheated in the upper preheating chamber is dropped into the lower preheating chamber. The sucked metal scrap is deposited in the downstream exhaust gas duct, or enters the deodorization tower or cooler, and also the dust collector, which interferes with the smooth flow of the exhaust gas, thereby impairing the function of the deodorization tower, the cooler, and the dust collector. There is a problem to say.

The problem to be solved by the present invention is that in the conventional furnace top preheating equipment, a part of the metal scrap to be preheated is sucked into the exhaust gas duct connected to the shaft wall of the furnace top preheater, and the sucked metal scrap is exhaust gas duct. It is deposited in the inside, enters the deodorization tower or cooler, and also the dust collector, which causes trouble in the smooth flow of the exhaust gas, thereby impairing the function of the deodorization tower, the cooler, and the dust collector.

The present invention, which solves the above-mentioned problems, has a preheating device equipped with a preheating device equipped at the top of a furnace of a melting furnace, and an exhaust gas treatment device connected to the preheating device. The equipped shaft and an opening and closing finger for partitioning one preheating chamber in the shaft are connected, and an exhaust gas duct having dampers is connected to an upper portion of the shaft wall forming the preheating chamber and a shaft wall lower than the preheating chamber, respectively. These exhaust gas ducts are joined on the downstream side thereof, and the exhaust gas treatment device is connected to the exhaust gas duct after the joining.

In addition, the present invention is a furnace top preheating equipment comprising a preheating device equipped at the top of the furnace of the furnace, and an exhaust gas treatment device connected to the preheater, wherein the preheater is a shaft equipped at the top of the furnace of the furnace, An exhaust gas duct having an openable finger for partitioning two or more preheating chambers in the shaft in the vertical direction and having dampers on the shaft walls below the upper and lowermost preheating chambers of each shaft wall forming each preheating chamber is provided. These exhaust gas ducts are joined on the downstream side thereof, and the exhaust gas treatment device is connected to the exhaust gas duct after the joining.

Also in the furnace top preheating facility which concerns on the present invention as described above, it is equipped with the preheating apparatus equipped with the furnace top part of a melting furnace like the conventional furnace top preheating installation, and the waste gas processing apparatus connected to this preheating apparatus. The apparatus is provided with a shaft equipped at the top of the furnace of the melting furnace and an openable finger that partitions two or more preheating chambers in the shaft in one or a vertical direction. In the furnace top part preheating installation which concerns on the above-mentioned this invention, when one preheating chamber is formed in the shaft equipped in the furnace top part, the shaft in the upper part of the shaft wall which forms this preheating chamber, and the lower part than this preheating chamber. Exhaust gas ducts each having a damper are connected to the wall. In the case where two or more preheating chambers are formed in the shaft provided at the top of the furnace in the vertical direction, the exhaust gas ducts each having a damper on the shaft wall above the shaft wall and the lowermost preheating chamber forming each preheating chamber. Is connected. More specifically, the preheating chamber is partitioned in the upper and lower two stages by the upper and lower two-stage fingers that can be opened and closed in the shaft provided at the top of the furnace, and the shaft wall lower than the upper and lower preheating chambers of the shaft wall forming the upper preheating chamber. In the case where the bypass duct is placed between the exhaust pipe and the exhaust gas duct having a damper connected to the upper part of the shaft wall forming the preheating chamber at the upper end, the exhaust gas duct having the damper is also formed at the upper part of the shaft wall forming the lower preheating chamber. A gas duct is connected, and the exhaust gas duct which has a damper is also connected to the shaft wall lower than a lower preheating chamber.

In either case, the respective exhaust gas ducts each having a damper connected to the shaft wall are joined at their downstream side, and the exhaust gas treatment device is connected to the exhaust gas duct after the joining. In the furnace top preheating facility of the present invention, as will be described in detail later, by the opening and closing operation of the damper of each exhaust gas duct connected to the shaft wall, the metal scrap is prevented from being sucked into the exhaust gas duct from its source.

The present invention, which solves the electric problem, further comprises a preheating device equipped with a preheating device equipped at the top of a furnace of a melting furnace and an exhaust gas treating device connected to the preheating device. The buffer tower is connected to the exhaust gas duct of the preheater, and the buffer tower includes an enclosed tower, an exhaust gas inlet provided at the bottom of the tower, and an exhaust gas provided at the top of the tower. An outlet and a burner attached to the tower are provided, and the cross-sectional area of the tower is larger than the cross-sectional area of the exhaust gas duct.

In addition, the present invention is a furnace top preheating equipment comprising a preheater equipped at the top of the furnace of the furnace and an exhaust gas treatment device connected to the preheater, wherein the exhaust gas treatment device includes a buffer tower, and the buffer tower Is connected to the exhaust gas duct of the preheater, and the buffer tower includes an airtight tower, an intermediate section for forming a U-shaped flow path in the tower, and an exhaust installed above the tower at an upstream side of the U-shaped flow path. The gas inlet, the exhaust gas outlet installed in the upper part of the tower downstream of this U-shaped flow path, and the burner attached to the tower are provided, and the cross-sectional area of the U-shaped flow path upstream is larger than the cross-sectional area of the said exhaust gas duct. It relates to a furnace preheating equipment, characterized in that formed.

Also in the furnace top preheating facility according to the present invention as described above, like the conventional furnace top preheating facility, a preheater equipped at the furnace top of the melting furnace and an exhaust gas treatment device connected to the preheater are provided. The apparatus is provided with a shaft equipped at the top of the furnace of the melting furnace and an openable finger that partitions two or more preheating chambers in the shaft in one or a vertical direction. In the furnace top preheating equipment according to the present invention as described above, a buffer tower is connected to the exhaust gas duct of the preheater equipped in the furnace top of the melting furnace, preferably near the preheater. The buffer tower includes a closed tower, an exhaust gas inlet and an exhaust gas outlet installed in the tower, and a burner attached to the tower. The exhaust gas inlet is installed at the bottom or top of the tower, the exhaust gas outlet is installed at the top of the tower, and one or more burners have a sufficient contact with the flame of the burner and the exhaust gas introduced into the tower. Is attached.

When the exhaust gas inlet is installed at the bottom of the tower, the cross-sectional area of the exhaust gas introduced into the tower from the exhaust gas inlet rises in the tower and is exhausted from the exhaust gas outlet installed at the top of the tower. In the tower formed larger than the cross-sectional area of the exhaust gas duct, as the flow velocity of the exhaust gas becomes slow, metal scrap accompanying the exhaust gas is captured, and carbon monoxide contained in the exhaust gas is burned with the flame of the burner. When the exhaust gas inlet is installed at the top of the tower, an intermediate section for forming a U-shaped flow path is attached to the tower, and an exhaust gas inlet is placed at the upper part of the tower above the U-shaped flow path upstream and the downstream of the U-shaped flow path. The exhaust gas outlet is installed in the upper part of the tower, and the exhaust gas introduced into the tower from the exhaust gas inlet descends the upstream side of the U-shaped flow path, and rises downstream of the U-shaped flow path to be exhausted from the exhaust gas outlet. On the upstream side of the U-shaped flow path upstream of the cross section of the exhaust gas duct, the metal scrap accompanying the exhaust gas is captured as the flow rate of the exhaust gas is slowed. The carbon monoxide contained in the burner is burned by the flame of the burner.

In either case, even when metal scrap is sucked into the exhaust gas duct of the furnace top preheater by the above-mentioned buffer tower connected to the uppermost side of the exhaust gas treatment device, the metal scrap is contained in the downstream exhaust gas duct. It does not accumulate or enter the deodorizing tower or cooler or the dust collector, and can maintain the smooth flow of exhaust gas, and can also maintain the function of the deodorizing tower or the cooler or dust collector. In addition, the carbon monoxide contained in the exhaust gas can be burned by the flame of the burner attached to the buffer tower, and the odor component and the oil component can also be burned and decomposed.

Furthermore, the present invention, which solves the electric problem, relates to a furnace top preheating facility comprising the preheating device and exhaust gas treatment device of the present invention as described above. As described above, the preheater includes a shaft equipped at the top of the furnace, and an openable finger that partitions two or more preheating chambers in one or up and down directions in the shaft, and each of which includes an exhaust gas duct having a damper. It connected to the wall and joined each exhaust gas duct from the downstream side. In addition, the exhaust gas treating apparatus has a buffer tower as described above on the uppermost side thereof, and connects the buffer tower to the exhaust gas duct after joining. In the furnace top preheating system of the present invention, by preventing opening and closing of the metal scrap into the exhaust gas duct by opening and closing operation of the damper of each exhaust gas duct connected to the shaft wall, and at the same time, the exhaust gas is caused for some reason. The metal scrap sucked into the duct is captured by the buffer tower, and the carbon monoxide contained in the exhaust gas discharged from the preheater is burned.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an overall view schematically showing in longitudinal section a furnace top preheating facility according to the invention.

Figure 2 is a general view schematically showing in longitudinal section another furnace top preheating equipment according to the present invention.

3 is an overall view schematically showing, in some longitudinal section, a further furnace top preheating arrangement according to the invention;

4 is an overall view schematically showing, in some longitudinal section, a further furnace top preheating arrangement according to the invention;

Fig. 5 is an overall view schematically showing, in some longitudinal section, a further furnace top preheating arrangement according to the invention.

6 is an overall view schematically showing, in some longitudinal section, still another furnace top preheating arrangement according to the invention;

※ Explanation of symbols about main part of drawing ※

11, 12, 111, 112... Melting furnaces 21, 22, 123, 133. shaft

41 to 43, 124, 125, l34, 135. Finger

51 to 53, 126, 127, 136, 137... Preheating room

61 to 66. Dampers 71 to 75 141 to 143, 145 to 147... Exhaust duct

101, 102... Exhaust gas treatment system

144, 148. Suction blowers 151, 161... Buffer tower

154, 155, 167, 168... Burner 163. U-shaped euro 164... Middle section

171, 172. Coolers 181, 182... Dust collector

Brief Description of Drawings [Fig. 1] Fig. 1 is an overall view schematically showing the furnace top preheating equipment according to the present invention in a longitudinal section. A cylindrical shaft 21 is provided at the top of the furnace of the melting furnace l1, and an opening and closing door 31 is provided at the upper portion of the shaft 21, and a finger 41 which can be opened and closed at the middle of the shaft 21 is provided. It is equipped. In FIG. 1, one preheating chamber 51 is partitioned by a finger 41 in the shaft 21, and a metal scrap A is loaded in the preheating chamber 51. The exhaust gas duct 71 which has the damper 61 is connected to the upper part of the shaft wall 21a which forms the preheating chamber 5l, and is damper 62 to the shaft wall 21b lower than the preheating chamber 51. FIG. And an exhaust gas duct 72 are connected, and the exhaust gas ducts 71 and 72 are connected to the exhaust gas treatment apparatus 101 after joining on the downstream side thereof.

In FIG. 1, the damper 61 is normally opened, the damper 62 is closed, and the hot exhaust gas generated in the melting furnace l1 is introduced into the preheating chamber 51 through the finger 41, thereby preheating the chamber 51. Preheat the metal scrap A loaded in). The exhaust gas after preheating is exhausted through the paths of the exhaust gas duct 71, the damper 61, and the exhaust gas treatment device 101. When the finger 41 is pivoted downward to open, and the preheated metal scrap A is introduced into the furnace from the preheating chamber 51, the damper 61 is opened and the damper 62 is closed, so that a part of the metal scrap A is closed. To prevent suction into the exhaust gas duct 72. In addition, when opening and closing the door 31 and loading a new metal scrap into the preheating chamber 51 from a bucket (not shown), the damper 61 is closed and the damper 62 is opened to open a portion of the metal scrap. The suction to the duct 71 is prevented.

Fig. 2 is an overall view schematically showing, in longitudinal section, another furnace top preheating facility according to the invention. A cylindrical shaft 22 is provided at the top of the furnace of the melting furnace 12, and an opening and closing door 32 is provided at the upper portion of the shaft 22, and the finger which can be opened and closed in two stages at the middle of the shaft 22 is provided. 42 and 43 are provided. In FIG. 2, two preheating chambers 52 and 53 are divided into two upper and lower fingers 42 and 43 in the shaft 22, and two metal preheating chambers 52 and 53 are arranged in the preheating chamber 52. The metal scrap C is loaded in the preheating chamber 53. Exhaust gas duct having damper 63 on top of shaft wall 22a forming preheating chamber 52.

An exhaust gas duct 74 having a damper 64 is connected to an upper portion of the shaft wall 22b that forms the preheating chamber 53, and the lower shaft is lower than the preheating chamber 53. An exhaust gas duct 75 having a damper 65 is connected to the wall 22c, and the exhaust gas ducts 73, 74, and 75 are joined to the exhaust gas treatment device 102 after joining downstream thereof. Connected. A bypass duct 76 having a damper 66 is placed between the upper portion of the shaft wall 22a forming the preheating chamber 52 and the shaft wall 22c lower than the preheating chamber 53.

In FIG. 2, normally, the dampers 63 and 65 are closed and the dampers 64 and 66 are opened, and a part of the hot exhaust gas generated in the melting furnace 12 is lowered through the finger 43. To the preheat chamber 53, preheating the metal scrap C loaded in the preheat chamber 53, while preserving the remaining portion of the hot exhaust gas generated in the melting furnace 12 through the bypass duct 76. The metal scrap B introduced into 52 and preloaded in the preheating chamber 52 is preheated. Then, the exhaust gases after preheating thereof are exhausted through the paths of the exhaust gas duct 74, the damper 64, and the exhaust gas processing device 102. When the finger 43 is pivoted downward to open, and the preheated metal scrap C is introduced into the furnace from the preheating chamber 53, the dampers 63 and 64 are opened and the dampers 65 and 66 are closed. This prevents a portion of the metal scrap C from being sucked into the exhaust gas duct 75 or the bypass duct 76. In addition, when the finger 42 is pivoted downward to open, and the preheated metal scrap B is dropped from the preheating chamber 52 to the preheating chamber 53, the dampers 63 and 65 are opened, and the dampers 64, By closing 66, a portion of the metal scrap B is prevented from being sucked into the exhaust gas duct 74. Furthermore, when opening and closing the door 32 and loading a new metal scrap from the bucket, for example, into the preheating chamber 52, the dampers 63 and 66 are closed and the dampers 64 and 65 are removed. The opening prevents a portion of the metal scrap from being sucked into the duct 73.

Although not shown, the shaft can be installed to be movable relative to the melting furnace, and in the case of forming the preliminary chamber in multiple stages of three or more stages in the shaft, as shown in FIG. Exhaust gas ducts having dampers are connected to the shaft walls below the upper and lower preheating chambers, respectively.

3 is an overall view schematically showing, in some longitudinal section, a further furnace top preheating arrangement according to the invention. The preheater 121 is provided at the top of the furnace of the melting furnace 111, and the buffer tower 151 is connected to the exhaust gas duct 141 of the preheater 121. The cooler 171 is connected to the downstream side of the buffer tower 151 via the exhaust gas duct 142, and the dust collector is further downstream of the cooler 171 via the exhaust gas duct 143 and the suction blower 144. 181 is connected.

The preheater 121 is constructed of a closed shaft 123 having an opening and closing door 122 thereon. In the shaft 123, two stages of preheating chambers 126 and 127 are partitioned in the vertical direction by fingers 124 and 125 which can be opened and closed, and an upper portion of the shaft wall forming the upper preheating chamber 126. And a bypass duct 128 between the lower and the shaft wall lower than the preheating chamber 127, and the exhaust gas duct 141 is connected to the upper part of the shaft wall forming the lower preheating chamber l27. have.

The buffer tower 151 includes a closed tower 152, an exhaust gas inlet 153 provided under the side wall of the tower 152, and a tower 152 positioned on the opposite side of the exhaust gas inlet 153. The burner 154 attached to the lower side of the side wall, the burner 155 attached to the middle of the side wall of the tower 152 located on the opposite side of the burner 154, and the tower 152 located on the opposite side of the burner 155 The exhaust gas outlet 156 provided in the upper side wall and the opening-closing door 157 attached to the lower part of the tower 152 are provided. The exhaust gas duct 141 is connected obliquely downward to the exhaust gas inlet 153, and the exhaust gas duct 142 is connected to the exhaust gas outlet 156. The exhaust gas discharged from the preheater 121 is guided downwardly downward from the exhaust gas inlet 153 into the tower 152 through the exhaust gas duct 141, and also burners 154, 155 Are attached obliquely downward to the side wall of the tower 152 as if these flames faced or blocked the flow of exhaust gas in the tower 152.

In the preheater 121, when the metal scrap D preheated in the upper preheating chamber 126 is dropped into the lower preheating chamber 127, a part of the metal scrap D is sucked into the exhaust gas duct 141, The cross-sectional area of the exhaust gas duct 141 is measured between the exhaust gas introduced from the exhaust gas inlet 153 into the tower 152 until it rises in the tower l52 and is exhausted from the exhaust gas outlet 156. In the larger tower 152, as the flow rate of the exhaust gas becomes slower, metal scrap accompanying the exhaust gas is collected and collected at the lower portion, and carbon monoxide contained in the exhaust gas is burner 154, ( It burns with the flame of 155, and also burns and decomposes the odor component and oil component contained in the said exhaust gas with the flames of burners 154 and 155. The entrained metal scrap is thus captured, the carbon monoxide is combusted, the odor component and the oil component are further burned and decomposed, and the exhaust gas is cooled by the cooler 171 on the downstream side. To remove dust from the exhaust gas.

4 is an overall view schematically showing, in some longitudinal section, a further furnace top preheating arrangement according to the invention. The preheater 131 is provided at the top of the furnace of the melting furnace 112, and the buffer tower 161 is connected to the exhaust gas duct 145 of the preheater 131. The cooler 172 is connected to the downstream side of the buffer tower 161 via the exhaust gas duct 146, and the dust collector is further downstream of the cooler 172 via the exhaust gas duct 147 and the suction blower 148. 182 is connected.

Opening and closing door 132 constituting the preheater 131, shaft 133 of the closed system, fingers 134, 135, preheating chambers 136, 137 of the upper and lower stages, and bypass duct 138 The mutual relationship is the same as the case of the preheating apparatus 121 shown in FIG.

The buffer tower 161 includes a closed tower 162, an intermediate section 164 forming a U-shaped flow path 163 in the tower 162, and a tower 162 at an upstream side of the U-shaped flow path 163. The exhaust gas inlet 165 provided at the upper side wall of the upper side, the exhaust gas outlet 166 provided at the upper side wall of the tower 162 on the downstream side of the U-shaped flow path 163, and the U-shaped flow path 163. A burner 167 attached to the lower sidewall of the tower 162 on the upstream side of the top, a burner 168 attached to the middle of the sidewall of the tower 162 on the downstream side of the U-shaped flow path 163, The opening and closing door 169 attached to the lower part of the tower 162 is provided. An exhaust gas duct 145 is connected to the exhaust gas inlet 165, an exhaust gas duct 146 is connected to the exhaust gas outlet 166, and burners 167 and 168 have a flame top. It is attached obliquely downward to the side wall of the tower 162 so as to block the flow of the exhaust gas in the U-shaped flow path 163 in the 162.

In the preheater 131, when the metal scrap E preheated in the preheating chamber 136 at the upper end is dropped into the preheating chamber 137 at the lower end, a part of the metal scrap E is sucked into the exhaust gas duct 145, The exhaust gas introduced into the tower 162 from the exhaust gas inlet 165 descends the upstream side of the U-shaped flow path 163, and rises the downstream side of the U-shaped flow path 163 to exhaust the exhaust gas at the exhaust gas outlet 166. In the upstream U-shaped flow path 163 in which the cross-sectional area is larger than the cross-sectional area of the exhaust gas duct 145, the metal scrap accompanies the exhaust gas as the flow velocity of the exhaust gas becomes slow. Captured and collected in the lower part, and the carbon monoxide contained in the exhaust gas is burned by the flames of burners 167 and 168, and the odor component and oil component contained in the exhaust gas are burner 167 and 168. Decompose into flames of The entrained metal scrap is thus captured, the carbon monoxide is combusted, the odor component and the oil component are further burned and decomposed, and the exhaust gas is cooled by the cooler 172 on the downstream side. To remove dust from the exhaust gas.

5 is an overall view schematically showing, in some cross-section, a further furnace top preheating plant according to the invention. The furnace top preheating installation of FIG. 5 is an exhaust gas treating apparatus 102 of the furnace top preheating installation of FIG. 2, and the exhaust gas treating apparatus of the furnace top preheating installation of FIG. 3, that is, the buffer tower 151. The downstream apparatus is incorporated rather than this including. For convenience, the same code as the preheater of FIG. 2 is used for the preheater, and the same code as the exhaust gas treatment device of FIG. Although the description of the relationship, the action, and the like is omitted, the mutual relationship, the action, and the like of each component requirement indicated by these symbols are as described above with reference to FIGS. 2 and 3. In the furnace top preheating facility of FIG. 5, these exhaust gas ducts are opened and closed by the damper 63 to 66 provided in the exhaust gas ducts 73 to 75 and the bypass duct 76. 73) to 75 and the exhaust gas duct 141 after joining prevent the metal scrap from being sucked from the source, and at the same time, the metal scrap sucked into the exhaust gas duct 141 after joining for some reason is absorbed. 151, and further, combustion of carbon monoxide in the exhaust gas and combustion decomposition of malodorous components or oil components.

6 is an overall view schematically showing, in some cross section, another furnace top preheating facility according to the invention. The furnace top preheating installation of FIG. 6 is an exhaust gas treating apparatus 102 of the furnace top preheating installation of FIG. 2, and the exhaust gas treating apparatus of the furnace top preheating installation of FIG. 4, that is, the buffer tower l61. The downstream apparatus is incorporated rather than this including. For convenience, the same code as the preheater of FIG. 2 is used for the preheater, and the same code as the exhaust gas treatment device of FIG. Although the description of the relationship, action, and the like is omitted, the mutual relationship, action, and the like of each of the structural requirements indicated by these symbols are as described above with reference to FIGS. 2 and 4. In the furnace top preheating installation of FIG. 6, these exhaust gas ducts are opened and closed by the operation of opening and closing the dampers 63 to 66 provided in the exhaust gas ducts 73 to 75 and the bypass duct 76. 73) to (75) and the exhaust gas duct 145 after joining prevent the metal scrap from being sucked from the source, and at the same time the metal scrap sucked into the exhaust gas duct 145 after joining for some reason buffer tower 161 ), And combustion of carbon monoxide in the exhaust gas and combustion decomposition of odorous components or oil components.

Although not shown, it goes without saying that the exhaust gas treating apparatus 10l of the furnace top preheating apparatus of FIG. 1 can be incorporated into the exhaust gas treating apparatus of the furnace top preheating apparatus of FIG. 3 or 4. .

As is already apparent, in the present invention described above, the metal scrap is prevented from being sucked into the exhaust gas duct of the furnace top preheater, and even if a part of the metal scrap is sucked, the metal scrap is disposed on the uppermost side of the exhaust gas treatment device. Because of the trapping, the metal scrap does not accumulate in the downstream exhaust gas ducts or enter the deodorization tower or cooler or dust collector, thus maintaining a smooth flow of the exhaust gas, and furthermore, the deodorization tower or cooler dust collector. The effect is that the function of the device can be maintained.

Claims (6)

In a furnace top preheating facility comprising a preheater installed at the top of a furnace of a furnace and an exhaust gas treatment device connected to the preheater, the preheater includes a shaft equipped at the top of the furnace of a furnace and one preheater in the shaft. Exhaust ducts having an openable finger for partitioning the chamber and having dampers are respectively connected to the upper part of the shaft wall forming the preheating chamber and the shaft wall lower than the preheating chamber, and these exhaust gas ducts are downstream thereof. A furnace top preheating facility, which is joined from the side and is connected to an exhaust gas duct after joining. In a furnace top preheating facility comprising a preheater equipped at the top of a furnace of a furnace and an exhaust gas treatment device connected to the preheater, the preheater includes a shaft equipped at the top of a furnace of the furnace, and a vertical direction in the shaft. And an exhaust gas duct having an openable finger for dividing two or more preheating chambers, each having a damper connected to an upper portion of each shaft wall forming the preheating chamber and a shaft wall lower than the lowermost preheating chamber. The exhaust gas ducts of the furnace are joined on the downstream side thereof, and an exhaust gas treatment device is connected to the exhaust gas duct after the joining. A furnace top preheating facility comprising a preheater equipped at the top of a furnace of a furnace and an exhaust gas treatment device connected to the preheater, wherein the exhaust gas treatment device includes a buffer tower, and the buffer tower exhausts the preheater. The buffer tower is connected to the gas duct, and the shock absorbing tower is attached to the tower of the closed system, the exhaust gas inlet provided at the bottom of the tower, the exhaust gas outlet provided at the top of the tower, and the tower. The burner top part preheating apparatus provided with the burner, Comprising: The cross section of the tower is formed larger than the cross section of the said exhaust gas duct. A furnace top preheating facility comprising a preheater equipped at the top of a furnace of a furnace and an exhaust gas treatment device connected to the preheater, wherein the exhaust gas treatment device includes a buffer tower, and the buffer tower exhausts the preheater. The buffer tower is connected to the gas duct, and the buffer tower includes an airtight tower, an intermediate section for forming a U-shaped flow path in the tower, an exhaust gas inlet provided in an upper portion of the tower located upstream of the U-shaped flow path, and It is provided with the exhaust gas outlet installed in the upper part of the said tower on the downstream side of a U-shaped flow path, and the burner attached to the said tower, The cross-sectional area of the upstream of the said U-shaped flow path is formed larger than the cross-sectional area of the said exhaust gas duct, It is characterized by the above-mentioned. Furnace top preheating equipment. The exhaust gas treating apparatus includes a buffer tower, the buffer tower is connected to an exhaust gas duct after joining the preheater, and the buffer tower includes a sealed tower and The exhaust gas inlet provided in the lower part of the tower, the exhaust gas outlet provided in the upper part of the tower, and the burner attached to the said tower are provided, and the cross-sectional area of the tower is formed larger than the cross-sectional area of the said exhaust gas duct. Furnace top preheating equipment, characterized in that. The exhaust gas treating apparatus includes a buffer tower, the buffer tower is connected to an exhaust gas duct after joining the preheater, and the buffer tower includes a sealed tower and An intermediate section forming a U-shaped flow path in the tower, an exhaust gas inlet provided in an upper portion of the tower upstream of the U-shaped flow path, an exhaust gas outlet provided in an upper portion of the tower on the downstream side of the U-shaped flow path, and a corresponding tower And a burner attached to the upper portion, wherein the cross-sectional area of the upstream side of the U-shaped flow path is formed to be larger than that of the exhaust gas duct.