JP2020006417A - Cooling device of metal strip - Google Patents

Abstract

To provide a cooling device of a metal strip which can quickly and efficiently cool the heated metal strip during a short conveyance distance, in the cooling device of the metal strip for cooling the heated metal strip continuously conveyed.SOLUTION: Upon cooling of a heated metal strip W continuously conveyed, an air nozzle 10 is provided so as to face the conveyed and heated metal strip, a pair of linear nozzles 11, 11 extended in a width direction of the metal strip against which gas is sprayed are provided so as to be opposed to each other via a required interval on the upstream side and the downstream side in the conveyance direction of the metal strip, so as to be protruded to the metal belt side and such that cooling medium c is sprayed together with gas toward the metal strip from the linear nozzle.SELECTED DRAWING: Figure 2

Description

  TECHNICAL FIELD The present invention relates to a metal band cooling device for cooling a continuously conveyed heated metal band. In particular, the present invention is characterized in that the heated metal strip can be rapidly and efficiently cooled within a short transport distance when cooling the continuously transported heated metal strip.

  2. Description of the Related Art Conventionally, as shown in Patent Documents 1 to 4, cooling of a heated metal band is performed while a heated metal band is continuously conveyed.

  Here, in cooling the continuously conveyed heated metal strip, in the technique disclosed in Patent Document 1, the continuously conveyed heated metal strip is arranged along the width direction of the metal strip. A plurality of cooling water nozzles are provided in a row, and cooling water is dropped from each cooling water nozzle onto the metal band. In Patent Literature 2, the cooling water nozzles are continuously conveyed. A plurality of spray nozzles are provided below the heated metal strip along the width direction of the metal strip, and the spray nozzles spray cooling water from under the metal strip. .

  However, as shown in Patent Literatures 1 and 2, when water for cooling is directly sprayed on a heated metal strip to be conveyed, the sprayed water flows from the metal strip before being evaporated. As a result, the metal strip cannot be efficiently cooled by effectively utilizing the evaporation heat of water.To sufficiently cool the heated metal strip, a large amount of cooling water must be used for a long time. There was a problem that it was necessary to spray.

  Further, in Patent Document 3, a heated metal band is guided to a cooling zone to be cooled, and the metal band is further floated by a first fumarole floater provided downstream of the cooling zone in the transport direction of the metal band. The metal band is further cooled in the water tank, the metal band thus cooled is led out from the water tank, and the second fumarole is provided on the downstream side in the transport direction of the metal band. The figure shows a state in which the sheet is transported while being floated by a floater.

  However, as shown in Patent Literature 3, after a heated metal band is guided to a cooling zone to be cooled, a first fumarole floater provided with the metal band downstream of the cooling zone in the transport direction of the metal band. Is transported in a floating state and guided into a water tank, the metal band is further cooled in the water tank, and the metal band thus cooled is drawn out of the water tank to be transported downstream of the metal band in the transport direction. When transported in a state of being floated by the fumarolic floater of No. 2, there is a problem that the equipment becomes large and the cost is extremely high.

  Further, in Patent Literature 4, a gas is injected from a floater to the metal band, the metal band is conveyed in a floating state, and heat-treated, and then, after cooling the metal band after the heat treatment, the metal band is cooled. After pre-cooling both width ends, the metal strip is guided to a cooling floater, and a low-temperature cooling gas is injected into the metal strip in the cooling floater to rapidly cool the metal strip. Are shown.

  However, as shown in Patent Literature 4, it is difficult to rapidly cool the metal band by injecting a gas such as a cooling gas into the metal band in a cooling floater, and rapidly cooling the metal band. In order to achieve this, it is necessary to inject a very low-temperature cooling gas, so that the cost required to sufficiently cool the cooling gas is high and that a low-temperature cooling gas is strongly injected into a metal strip. There was a problem that it became necessary.

  Further, in Patent Document 5, in a strip floating pressure pad (floater) for spraying a fluid under a continuously conveyed strip (metal band) to cause the strip to float and convey the strip, the strip opposing surface has front and rear sides. A parallel slit nozzle is provided, and at least one set of straightening plates protruding toward the end is provided symmetrically at the center between the slit nozzles, and a plurality of fluid jets are provided inside the straightening plates along the straightening plate. The one provided with holes is shown.

  Here, what is shown in patent document 5 sprays a fluid to the lower surface of a strip from the slit nozzle or the fluid ejection hole, and suppresses the flow of the fluid from the lower surface of the strip to the side by the straightening plate. In addition, the levitation force and stability of the strip by the fluid sprayed on the lower surface of the strip are increased, and even when the amount of the fluid sprayed on the lower surface of the strip from the slit nozzle or the fluid ejection hole is reduced, the strip is stably floated and transported It does not show that the heated metal strip is cooled while the heated metal strip is continuously conveyed.

JP-A-53-99311 JP 2011-131248 A JP-A-61-253329 (JP-B-6-6751) JP-A-2017-66481 JP-A-6-10065 (JP-B-7-30416)

  An object of the present invention is to provide a metal band cooling device for cooling a continuously conveyed heated metal band, so that the heated metal band can be rapidly and efficiently cooled over a short conveyance distance. Is what you do.

  In the first metal strip cooling device according to the present invention, in order to solve the above-described problems, in the metal strip cooling device that cools the continuously transported heated metal strip, the transported heated strip is cooled. An air nozzle is provided so as to face the metal band, and a pair of linear nozzles extending in the width direction of the metal band that blows a gas against the metal band are provided on the air nozzle, and the upstream side in the transport direction of the metal band. The cooling medium was sprayed from the straight nozzle toward the metal band together with the gas from the linear nozzle so as to protrude toward the metal band so as to face the downstream side with a required interval. .

  Then, as in the cooling device for the first metal band, the air nozzle provided so as to face the heated metal band to be conveyed, as described above, on the upstream side and the downstream side in the conveying direction of the metal band. A linear nozzle extending in the width direction of the metal band that blows a gas to the metal band at a required interval is provided so as to protrude toward the metal band, and the metal band is provided from the linear nozzle. When the cooling medium is sprayed together with the gas toward the metal strip, the cooling medium sprayed toward the metal strip comes into direct contact with the metal strip or comes into contact with the metal strip in the recess of the air nozzle between the linear nozzles. The cooling medium sprayed by the heat of the metal strip is efficiently evaporated, and the metal strip heated by the heat of evaporation at the time of evaporation is quickly and efficiently cooled.

  Further, in the second metal band cooling device of the present invention, in order to solve the above-described problem, the second metal band cooling device that cools the continuously conveyed heated metal band is conveyed. An air nozzle is provided so as to face the heated metal band, and the air nozzle is provided with a pair of linear nozzles extending in the width direction of the metal band that blows a gas to the metal band, in the upstream of the metal band in the transport direction. The cooling medium is provided so as to protrude toward the metal band side so as to face the metal band side so as to oppose the downstream side and the downstream side at a required interval, and to be directed toward the metal band in the recess of the air nozzle between the pair of linear nozzles. A plurality of spray holes for spraying, spraying a gas from the linear nozzle toward the metal band, and cooling from the plurality of spray holes provided in the recess toward the metal band. And so as to spray the medium.

  Then, as in the cooling device for the second metal band, the air nozzle provided so as to face the heated metal band to be conveyed, as described above, on the upstream side and the downstream side in the conveying direction of the metal band. Gas is blown toward the metal band from a pair of linear nozzles provided to protrude toward the metal band side so as to face each other with a required interval, and to the concave portion between the pair of linear nozzles. When the cooling medium is sprayed toward the metal band from the plurality of spray holes provided, the cooling medium sprayed toward the metal band comes into direct contact with the metal band, or in the recess between the linear nozzles. The cooling medium, which is maintained and comes into contact with the metal strip, is sprayed efficiently by the heat of the metal strip, and the metal strip heated by the heat of evaporation at the time of evaporation is quickly and efficiently cooled.

  Further, in the cooling device for the second metal band, at least one set of straightening plates whose central portion protrudes toward the end portion is provided symmetrically in the concave portion, and the straightening plates are formed along the inside of these straightening plates. It is preferable to provide a plurality of spray holes. With this configuration, the cooling medium sprayed toward the metal band from the plurality of spray holes provided in the concave portion is regulated by the right and left straightening plates and flows to both sides in the width direction of the metal band to leak out. The cooling medium sprayed from these spray holes toward the metal strip is maintained in the recess between the linear nozzles and efficiently contacts the metal strip, and the cooling medium evaporates more reliably. As a result, the metal strip heated by the heat of evaporation at the time of evaporation is more quickly and efficiently cooled.

  In the cooling device for the second metal band, the cooling medium is sprayed toward the metal band from the plurality of spray holes provided in the recess between the pair of linear nozzles as described above, As in the invention of the cooling device for the first metal band, the cooling medium may be sprayed together with the gas from the linear nozzle toward the metal band. With this configuration, the cooling medium sprayed toward the metal band from the spray hole and the linear nozzle is brought into more contact with the heated metal band and evaporated, and is heated by evaporation heat at the time of evaporation. The metal strip is cooled more quickly and efficiently.

  Here, in the cooling device for the first and second metal bands, when the air nozzle is provided so as to face the heated metal band to be conveyed as described above, the heated air nozzle is conveyed to the heated metal band. It can be provided on the lower surface side or upper surface side of the metal band. Here, gas is blown from the linear nozzle to the metal band, and the metal band is transported in a state of being lifted so as not to contact the air nozzle, and the cooling medium sprayed toward the metal band is linearly formed. In order to be efficiently cooled by contact with the metal band in the recess between the nozzles, it is common to provide the air nozzle on the lower surface side of the heated metal band to be conveyed. However, it is also possible to provide the air nozzle on the upper surface side of the heated metal strip to be conveyed. Furthermore, the air nozzle provided on the lower surface side of the metal band and the air nozzle provided on the upper surface side of the metal band may be provided so as to face each other via the heated metal band to be conveyed.

  In the first metal band cooling device of the present invention, in the air nozzle provided so as to face the heated metal band to be conveyed, the required distance between the upstream side and the downstream side in the metal band conveyance direction as described above is provided. A linear nozzle extending in the width direction of the metal band that blows a gas onto the metal band through the metal band is provided so as to protrude toward the metal band, and the cooling medium is supplied from the linear nozzle to the metal together with the gas. In the cooling device for the second metal band, a plurality of spray holes are provided in the recess between the pair of linear nozzles, and the plurality of spray holes are directed toward the metal band from the plurality of spray holes. Because the cooling medium is sprayed, the cooling medium sprayed toward the metal band from the plurality of spray holes provided in the concave portion between the pair of linear nozzles or the pair of linear nozzles directly contacts the metal band. Both The mist cooling medium maintained in the concave portion between the linear nozzles comes into contact with the metal band, and the mist cooling medium is efficiently evaporated by the heat of the metal band. As a result, the heated metal strip is quickly and efficiently cooled.

In the cooling device for a metal band according to the embodiment of the present invention, in cooling the conveyed heated metal band by the air nozzle, a schematic plane showing a state in which the heated metal band is continuously conveyed over the air nozzle. FIG. In the cooling device for the first metal band in the above-described embodiment, a pair of straight lines provided so as to protrude toward the metal band side such that the upstream side and the downstream side of the metal band in the transport direction face each other at a required interval. FIG. 4 is a schematic cross-sectional explanatory view showing a state in which a cooling medium is sprayed together with gas toward a heated metal strip conveyed from a nozzle. In the cooling device for the second metal band in the above-described embodiment, a pair of straight lines provided so as to protrude toward the metal band side so as to oppose the upstream side and the downstream side of the metal band in the transport direction at a required interval. A gas is blown toward the heated metal strip conveyed from the nozzle, and the cooling medium is directed toward the heated metal strip conveyed from a plurality of spray holes provided in the concave portion between the pair of linear nozzles. FIG. 3 is a schematic sectional explanatory view showing a state of spraying. In the cooling device for the second metal band in the above embodiment, a plurality of sets of rectifying plates whose central portions project toward the ends are provided symmetrically in the concave portion between the pair of linear nozzles, and the inside of these rectifying plates is provided. FIG. 3 is a schematic plan view showing a state in which a plurality of spray holes are provided along the line. In the cooling device for the first and second metal bands in the above embodiment, the cooling device is provided so as to protrude toward the metal band side so as to face the upstream side and the downstream side in the transport direction of the metal band at a required interval. The cooling medium is sprayed together with the gas toward the heated metal strip conveyed from the pair of linear nozzles, and the heating medium is conveyed from a plurality of spray holes provided in a concave portion between the pair of linear nozzles. FIG. 4 is a schematic cross-sectional explanatory view showing a state in which a cooling medium is sprayed toward a metal band that has been sprayed.

  Hereinafter, a metal strip cooling device according to an embodiment of the present invention will be specifically described with reference to the accompanying drawings. The cooling device for a metal strip according to the present invention is not limited to those described in the following embodiments, and can be appropriately modified and implemented without departing from the gist of the invention.

  Here, in the cooling device for the metal band W according to the first embodiment, as shown in FIG. 1, the metal band W that is heated and continuously conveyed is guided over the air nozzle 10, Through which the heated metal strip W is cooled.

  In the first embodiment, as shown in FIGS. 1 and 2, the upper surface of the air nozzle 10 facing the metal band W is provided with a metal band W orthogonal to the conveying direction of the metal band W. A pair of linear nozzles 11, 11 extending in the width direction are provided so as to protrude toward the metal band W in such a manner as to oppose the upstream side and the downstream side of the metal band W in the conveying direction at a required interval. Air is blown as a gas to the metal strip W conveyed from the straight nozzles 11 as described above. The linear nozzle 11 includes not only an elongated rectangular hole such as a slit but also a linear nozzle having a plurality of holes (not shown).

  Here, in the first embodiment, air is supplied from the air supply pipe 12 into the air nozzle 10, and water is supplied to the air nozzle 10 near the pair of linear nozzles 11, 11, respectively. The cooling medium c sprayed from each of the cooling medium spray nozzles 13 together with the air supplied from the air supply pipe 12 into the air nozzle 10 is provided. The air is blown toward the heated metal strip W conveyed over the air nozzle 10 through the linear nozzles 11, 11.

  As described above, when the cooling medium c is sprayed together with the air toward the heated metal strip W conveyed from each of the linear nozzles 11 and 11, the sprayed cooling medium c is heated. The cooling medium c which evaporates in direct contact with the metal strip W and remains without being evaporated is guided in a mist state into the recess 14 of the air nozzle 10 between the linear nozzles 11, 11. Then, it comes into contact with the heated metal strip W in order to evaporate.

  As a result, the cooling medium c sprayed together with the gas from each of the linear nozzles 11 and 11 toward the metal strip W comes into direct contact with the heated metal strip W and is heated in the recess 14. The cooling medium c sprayed by the heat of the metal band W in contact with the metal band W is efficiently evaporated, and the metal band W heated by the heat of evaporation during the evaporation is quickly and efficiently cooled. become.

  Next, in the cooling device for the metal strip W in the second embodiment, as shown in FIG. 3, similarly to the cooling device for the metal strip W in the first embodiment, the cooling device is heated and continuously conveyed. The metal strip W is guided over the air nozzle 10 and transported to pass over the air nozzle 10 to cool the heated metal strip W.

  Here, also in the second embodiment, as described above, the pair of linear nozzles 11, 11 along the width direction of the metal band W orthogonal to the transport direction of the metal band W is connected to the metal band W. Are provided so as to protrude toward the metal band W with the upstream side and the downstream side facing each other with a required interval therebetween in the conveying direction, and the metal band W conveyed from the linear nozzles 11 and 11 as described above. On the other hand, air is blown as gas.

  In the second embodiment, water or the like is introduced into the air nozzle 10 below the concave portion 14 of the air nozzle 10 between the pair of linear nozzles 11 provided so as to protrude toward the metal band W. A plurality of coolant spray nozzles 13 for ejecting the cooling medium c are provided, and a plurality of sprays for spraying the cooling medium c ejected from each of the coolant spray nozzles 13 toward the metal band W in the recess 14. A hole 15 is provided.

  In the second embodiment, when the air is supplied from the air supply pipe 12 into the air nozzle 10, the air supplied from the air supply pipe 12 is provided with the linear nozzles 11. Guide nozzles 12a, 12a are provided to guide the air nozzles 10, and air is guided to the respective linear nozzles 11, 11 through the guide channels 12a, 12a. Air is blown onto the conveyed metal band W, and air is supplied from the air supply pipe 12 into the air nozzle 10 in the concave portion 14 in which the spray hole 15 is provided. Of the cooling medium c ejected from the air nozzle 10 toward the metal strip W conveyed over the air nozzle 10 through a plurality of spray holes 15 provided in the concave portion 14. .

  In this manner, air is blown toward the heated metal strip W conveyed from each of the linear nozzles 11, 11, and at the same time, through a plurality of spray holes 15 provided in the concave portion 14 between the linear nozzles 11, 11. When the cooling medium c is sprayed together with the gas toward the heated metal strip W conveyed over the air nozzle 10, the sprayed cooling medium c is applied to the heated metal strip W in the recess 14. It comes into contact sequentially.

  As a result, in the second embodiment, the gas is sprayed together with the gas toward the heated metal strip W conveyed over the air nozzle 10 through the plurality of spray holes 15 provided in the recess 14. The cooled cooling medium c sequentially contacts the heated metal band W, the cooling medium c is efficiently evaporated by the heat of the metal band W, and the heated metal band W is heated by the evaporation heat during the evaporation. It will be cooled quickly and efficiently.

  Note that, as in the second embodiment, a plurality of cooling media c sprayed from the coolant spray nozzles 13 are sprayed toward the metal strip W into the concave portions 14 between the pair of linear nozzles 11, 11. In providing the spray holes 15, as shown in FIG. 4, a plurality of sets of rectifying plates 16 whose central portions protrude toward the ends are provided symmetrically in the concave portion 14, and are provided along the inside of these rectifying plates 16. Preferably, a plurality of the spray holes 15 are provided.

  In this manner, the cooling medium c sprayed toward the metal band W from the plurality of spray holes 15 provided in the recess 14 as described above is regulated by the right and left rectifying plates 16 and the metal band W Of the cooling medium c sprayed from the spray hole 15 toward the metal strip W is maintained in the recess 14 between the linear nozzles 11. As a result, the cooling medium c sprayed onto the heated and conveyed metal strip W efficiently contacts, the cooling medium c is more reliably evaporated, and the metal heated by the heat of evaporation at the time of evaporation. The band W is efficiently cooled more quickly.

  Also in the first embodiment, the cooling medium c ejected from the pair of linear nozzles 11 toward the metal band W flows on both sides in the width direction of the metal band W and leaks. In order to suppress the above, the straightening plate 16 as described above can be provided in the concave portion 14 between the linear nozzles 11 and 11.

  Next, in the cooling device for the metal strip W in the third embodiment, as shown in FIG. 5, similarly to the cooling device for the metal strip W in the first embodiment, the cooling device is heated and continuously transferred. The metal strip W is guided over the air nozzle 10 and transported to pass over the air nozzle 10 to cool the heated metal strip W.

  Here, also in the third embodiment, as described above, the pair of linear nozzles 11, 11 along the width direction of the metal band W orthogonal to the transport direction of the metal band W is connected to the metal band W. Are provided so as to protrude toward the metal band W with the upstream side and the downstream side facing each other with a required interval therebetween in the conveying direction, and the metal band W conveyed from the linear nozzles 11 and 11 as described above. On the other hand, air is blown as gas.

  In the third embodiment, a refrigerant spray nozzle 13 for spraying a cooling medium c such as water is provided in the air nozzle 10 in the vicinity of each of the linear nozzles 11, 11. A plurality of refrigerant spray nozzles 13 for jetting a cooling medium c such as water into the air nozzle 10 below the concave portion 14 between the linear nozzles 11 and 11 are provided. A plurality of spray holes 15 for spraying the ejected cooling medium c toward the metal strip W are provided.

  In the third embodiment, air is supplied from the air supply pipe 12 into the air nozzle 10 and sprayed from each of the refrigerant spray nozzles 13 together with the air supplied into the air nozzle 10. The cooling medium c is blown toward the heated metal strip W conveyed over the air nozzle 10 through each of the linear nozzles 11, 11, and passes through a plurality of spray holes 15 provided in the recess 14. The air is blown toward the heated metal strip W conveyed over the air nozzle 10.

  In this way, the cooling medium c sprayed with the gas from each of the linear nozzles 11 and 11 toward the heated metal band W conveyed over the air nozzle 10 is heated. While being in contact with W and being evaporated, the non-evaporated cooling medium c flows into the concave portion 14 and is heated over the air nozzle 10 through a plurality of spray holes 15 provided in the concave portion 14. The cooling medium c sprayed toward the metal strip W comes into contact with the heated metal strip W together with the cooling medium c, and the cooling medium c sprayed by the heat of the metal strip W is efficiently evaporated. Become like

  As a result, in the third embodiment, the cooling nozzle sprayed together with the gas from each of the linear nozzles 11, 11 toward the heated metal strip W conveyed over the air nozzle 10. The metal strip heated together with the medium c and the cooling medium c sprayed toward the heated metal strip W conveyed over the air nozzle 10 through the plurality of spray holes 15 provided in the recess 14. W, so that the cooling medium c sprayed by the heat of the metal strip W is efficiently evaporated, and the metal strip W heated by the heat of evaporation at the time of evaporation is quickly and efficiently cooled. Become.

  In the third embodiment, too, the cooling medium c ejected from the pair of linear nozzles 11 and 11 toward the metal band W, and the plurality of spray holes 15 provided in the recess 14 In order to prevent the cooling medium c sprayed toward the band W from flowing on both sides in the width direction of the metal band W to be conveyed and leaking out, the above-described recesses 14 between the linear nozzles 11 and 11 are provided. As shown in FIG. 4, a plurality of sets of straightening plates 16 whose central portions protrude toward the ends can be provided symmetrically.

  Further, in each of the embodiments shown in the drawings, the metal band W is transported in the horizontal direction. However, although not shown, the metal band W is transported in the vertical direction. It may be one that has been made. When the metal band W is transported in the vertical direction as described above, the air nozzle 10 does not need to function as a floater that lifts the metal band W.

10: Air nozzle 11: Linear nozzle 12: Air supply pipe 12a: Guide flow path 13: Refrigerant spray nozzle 14: Recess 15: Spray hole 16: Rectifying plate W: Metal band c: Cooling medium

In the first metal strip cooling device according to the present invention, in order to solve the above-described problems, in the metal strip cooling device that cools the continuously transported heated metal strip, the transported heated strip is cooled. An air nozzle is provided so as to face the metal band, and a pair of linear nozzles extending in the width direction of the metal band that blows a gas against the metal band are provided on the air nozzle, and the upstream side in the transport direction of the metal band. on the downstream side so as to face each other with a predetermined interval provided so as to protrude on the metal band side Rutotomoni, air nozzle a recess provided between said pair of straight nozzle, said from the linear nozzle of the The cooling medium is sprayed together with the gas toward the metal band, and the cooling medium sprayed together with the gas from each of the linear nozzles toward the metal band is accommodated in the concave portion. of And so as to contact to the genus band.

Then, as in the cooling device for the first metal band, the air nozzle provided so as to face the heated metal band to be conveyed, as described above, on the upstream side and the downstream side in the conveying direction of the metal band. Rutotomoni provided a linear nozzle extending in the width direction of the metal strip so as through a required distance blowing gas to the metal strip so as to project the metal band side, between the pair of straight nozzle When a cooling medium is sprayed together with gas from the linear nozzle toward the metal band, the cooling medium sprayed toward the metal band comes into direct contact with the metal band. with, the contained cooling medium in a recess provided in the air nozzle is in contact with the metal strip between the pair of straight nozzle, the cooling medium sprayed by the heat of the metal strip is effectively evaporated, Contact upon evaporation That the metal band is heated by heat of evaporation is to be cooled quickly and efficiently.

In the first metal band cooling device of the present invention, in the air nozzle provided so as to face the heated metal band to be conveyed, the required distance between the upstream side and the downstream side in the metal band conveyance direction as described above is provided. as the linear nozzle extending in the width direction of the metal strip for blowing a gas projecting metal strip side with respect to the metal strip so as to through the provided Rutotomoni, the air nozzle between said pair of straight nozzle the provided, linear Rutotomoni a cooling medium with gas from the nozzle is sprayed toward the metal strip, the cooling medium which is sprayed with a gas toward the metal strip from the linear nozzle of the recess, so as to contact with the metal strip by accommodated in the recess of the, also in the cooling device of the second metal strip is provided with a plurality of spray holes in the recess between the pair of linear nozzles, the plurality Since the cooling medium was sprayed from the spray hole toward the metal band, the cooling medium was sprayed toward the metal band from a plurality of spray holes provided in a concave portion between the pair of linear nozzles or the pair of linear nozzles. While the cooling medium comes into direct contact with the metal strip, the mist cooling medium maintained in the recess between the linear nozzles comes into contact with the metal strip and becomes mist-like by the heat of the metal strip. Is efficiently evaporated, and the metal strip heated by the heat of evaporation during the evaporation is quickly and efficiently cooled.

Claims (5)

  In a metal band cooling device for cooling a continuously conveyed heated metal band, an air nozzle is provided so as to face the conveyed heated metal band, and the air nozzle is provided with respect to the metal band. A pair of linear nozzles extending in the width direction of the metal band for blowing the gas are provided so as to protrude toward the metal band side so as to oppose the upstream side and the downstream side of the metal band in the transport direction at a required interval, A cooling device for a metal strip, wherein a cooling medium is sprayed together with a gas from the linear nozzle toward the metal strip.   In a metal band cooling device for cooling a continuously conveyed heated metal band, an air nozzle is provided so as to face the conveyed heated metal band, and the air nozzle is provided with respect to the metal band. A pair of linear nozzles extending in the width direction of the metal band to which gas is blown are provided so as to protrude toward the metal band side so as to oppose the upstream side and the downstream side of the metal band in the conveying direction at a required interval. A plurality of spray holes for spraying a cooling medium toward the metal band are provided in the recess between the pair of linear nozzles, and a gas is blown from the linear nozzle toward the metal band, and the recess is provided. A cooling medium is sprayed from the plurality of spray holes provided on the metal strip toward the metal strip.   3. The cooling device for a metal strip according to claim 2, wherein at least one pair of straightening plates whose central portion protrudes toward an end is provided symmetrically in the concave portion, and the spray is formed along the inside of these straightening plates. A cooling device for a metal strip, comprising a plurality of holes.   The cooling device for a metal band according to claim 2 or 3, wherein a cooling medium is sprayed together with gas from the linear nozzle toward the metal band. . The metal strip cooling device according to any one of claims 1 to 4, wherein the air nozzle is provided at least below the conveyed heated metal strip. Cooling system.

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