CN213530189U - Blowing device of cooling fog - Google Patents

Abstract

The utility model provides a jetting device of cooling mist of stick steel is cooled off to accessible simple device high efficiency and not take place warpage, crooked ground. In the cooling method, a rod steel (3) is bundled to form a rod steel bundle (4), two or more rod steel bundles (each of which is laid in parallel at a distance from each other to form a first layer, and two or more rod steel bundles as a second layer are laid in a cross shape at a distance from each other and at substantially right angles to the rod steel bundles of the first layer, and the rod steel bundles of the third and subsequent layers are stacked in a cross shape as necessary to form a two-layer or more laminated body (2) in which a cooling mist (5) composed of water droplets having an average particle diameter of 300 [ mu ] m or less is sprayed from a vertical gap formed by crossing the rod steel bundles in the laminated body from below the first layer to the vertical gap formed by the rod steel bundles of the first and second layers to cool the rod steel.

Description

Blowing device of cooling fog

Technical Field

The present invention relates to a cooling mist spraying apparatus for cooling a steel bar bundle (hereinafter, referred to as a steel bar bundle) formed by bundling a predetermined number of steel bars, which are conveyed to a cooling bed after hot rolling and further discharged from the cooling bed, into a predetermined length, and spraying mist-like cooling water (hereinafter, referred to as cooling mist) to an integrated body (hereinafter, referred to as a laminated body) formed by stacking the steel bar bundles in a multi-layered zigzag pattern.

Background

Generally, a bar steel is manufactured through the following processes: a billet (for example, a square billet or the like) obtained by continuous casting is conveyed to a heating furnace and heated to a predetermined temperature, and then hot-rolled to form a long round bar-shaped billet, which is then cooled in air by a cooling bed and cut into a predetermined length. Since the thus obtained steel bar is subjected to straightening and inspection processes, it is necessary to cool the steel bar to 50 ℃ or less from the viewpoint of improving the accuracy of these operations and improving the durability of the equipment used.

Therefore, a technique of further cooling the steel bar discharged from the cooling bed and cut into a predetermined length has been studied.

For example, a technique has been studied in which bundles of steel rods, each of which is formed by bundling a fixed number of steel rods, are transported by a crane or the like to form a stacked body in a cross shape, and are directly air-cooled. This cooling technique is a technique of slowly cooling by radiating heat to the atmosphere, and therefore can prevent deformation such as warping or bending of the steel bar. However, the time required for cooling is inevitably long, and varies depending on the size of the steel rods, the arrangement of the steel rods in the stacked body, the temperature around the stacked body, the air volume, and the like, but it takes about 3 to 5 days to cool the steel rods to 50 ℃. Therefore, there are problems that the place for placing the laminate is insufficient, and that much labor is required for stock management.

Patent document 1 discloses that a bundle of bar steels is cooled to M by air cooling_SAnd then carrying out immersion water cooling technology. This technique does not require stacking of the steel bar bundles into a stacked body, and can cool the steel bar bundles in a short time, so that the work efficiency of the cooling step can be improved. However, since the temperature of the cooling water in the water tank is increased by repeating immersion water cooling, it is necessary to circulate the cooling water between the water tank and the cooling tower in order to stably maintain the cooling capacity.

Therefore, the technique disclosed in patent document 1 requires not only a water tank and a cooling tower but also piping for circulating cooling water, and has a problem that the equipment becomes complicated and a large amount of labor is required for maintenance thereof. Further, rapid cooling by immersion water cooling also causes a problem that deformation such as warping and bending of the steel bar is likely to occur.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2017-221968

SUMMERY OF THE UTILITY MODEL

Problem to be solved by utility model

An object of the utility model is to eliminate prior art's problem, provide can carry out the jetting device of refrigerated cooling fog through simple device high-efficiently, and can not take place warpage, crooked ground to the bar steel.

Means for solving the problems

The inventors of the present invention have studied on a technique for efficiently cooling a bar steel by a simple device. Further, attention is paid to the fact that a laminated body in which steel rods are stacked in a multi-layer cross shape has excellent air permeability in a direction perpendicular to the ground surface of a place where the laminated body is placed. That is, if a technique for efficiently cooling the bar steel by the vertical air flow is developed, it is not necessary to provide large-scale equipment (for example, a water tank, a cooling tower, piping, and the like), and cooling can be performed by simple equipment (for example, a mist nozzle or the like).

As a result of the research, it was found that if cooling mist is sprayed to the vertical gap formed by intersecting the bundle of rod steels in a cross shape, the cooling mist easily passes through the inside of the laminated body, and therefore the entire laminated body can be efficiently cooled.

Next, the relationship between the size of the fine water droplets of the cooling mist and the cooling characteristics was investigated. As a result, it was found that the cooling capacity can be further improved by maintaining the particle diameter of the water droplets jetted in the vertical direction within an appropriate range, and the warping and bending of the bar can be prevented because the cooling rate is slower than the immersion water cooling. In such cooling by the cooling mist, a water tank or a cooling tower is not required.

When scale (e.g., deposit, rust, etc.) is generated on the surface of the steel bar by spraying the cooling mist, if the scale is removed after the spraying of the cooling mist is stopped, the steel bar can be subjected to straightening and inspection without trouble.

The present invention has been completed based on such findings.

That is, the present invention provides a cooling mist blowing device for a stacked body of two or more layers, the stacked body being formed by: a blowing device for forming a bundle of rod steels by bundling rod steels which are conveyed to a cooling bed after hot rolling is completed and are further cut into a predetermined length after being discharged from the cooling bed, forming the first layer by laying two or more bundles of rod steels substantially parallel to each other at intervals, stacking the two or more bundles of rod steels in a cross shape by laying the two or more bundles of rod steels substantially perpendicular to the bundle of rod steels of the first layer at intervals as the second layer, and stacking the bundles of rod steels of the third and subsequent layers in a cross shape as necessary, the blowing device comprising: a mist nozzle generating a cooling mist; and a control unit for controlling the average particle diameter of water droplets of the cooling mist blown onto the laminate to 300 [ mu ] m or less.

The present invention is a cooling mist blowing device for a stacked body of two or more layers, the stacked body being formed by: a blowing device for blowing hot-rolled steel rods, which are transported to a cooling bed after hot rolling, discharged from the cooling bed, and cut into predetermined lengths, into a predetermined number of steel rods, and bundled together to form a steel rod bundle, wherein two or more steel rod bundles are laid out in parallel with a space therebetween to form the first layer, and then, as the second layer, two or more steel rod bundles are laid out in parallel with a space therebetween and substantially at right angles to the steel rod bundle of the first layer to stack the steel rod bundles in a cross shape, and thereafter, the steel rod bundles of a third layer and subsequent layers are stacked in a cross shape as necessary, the blowing device comprising: a mist nozzle generating a cooling mist; and a control unit for controlling the average particle diameter of water droplets of the cooling mist blown onto the laminate to 300 [ mu ] m or less.

In the present invention, in order to obtain water droplets having a desired average particle size, a mist nozzle is used, which is designed and manufactured so as to obtain a mist of water droplets having a predetermined particle size on the premise of a predetermined amount of water, a predetermined water pressure, and the like.

That is, in the present invention, the average particle diameter (sauter average particle diameter) of the water droplets of the cooling mist is 300 μm or less means a case where the cooling mist is sprayed from a mist nozzle designed and produced so as to obtain the cooling mist composed of water droplets having an average particle diameter (sauter average particle diameter) of 300 μm or less.

The cooling mist blowing device of the present invention preferably includes a blower that generates an air flow for blowing the cooling mist from the mist nozzle to the stacked body. In the cooling mist blowing device according to the present invention, the control unit preferably causes the mist nozzle to spray the cooling mist from below the first layer to above the first layer, and the average particle diameter of the water droplets of the cooling mist is preferably in the range of 20 to 120 μm. Further, it is preferable that the resin composition,the length of each side of 4-16 positions in the laminated body is more than 0.1m and the area is 0.04m²The above longitudinal gap.

Effect of the utility model

According to the utility model discloses, can be through simple device high efficiency and do not produce warpage, crooked ground cooling bar steel to play the effect that is showing in the industry.

Drawings

Fig. 1 is a perspective view schematically showing an example of a laminated body in which rod steel bundles are stacked in a cross shape.

Fig. 2 is a perspective view schematically showing an example of the blowing device for the cooling mist.

Fig. 3 is a plan view schematically showing an example of spraying cooling mist to the laminate shown in fig. 1.

Fig. 4 is a side view schematically showing an example of spraying cooling mist to the laminated body shown in fig. 1.

Fig. 5 is a side view schematically showing another example of spraying cooling mist to the laminated body shown in fig. 1.

Description of the reference symbols

1 stand

2 laminated body

3 bar steel

4-bar steel bundle

5 Cooling mist

6-mist nozzle

7 blower

8 blowing device

Detailed Description

The steel bar is manufactured through the following steps: a billet (for example, a square billet or the like) obtained by continuous casting is conveyed to a heating furnace, heated to a predetermined temperature, and then hot-rolled to form a long billet in the shape of a round bar, and then air-cooled by a cooling bed, and then cut into a predetermined length (that is, a length required by product standards, for example, about 4 to 13 m). In order to further cool the thus obtained steel rods, a predetermined number of steel rods are bundled to form a bundle of steel rods, and the bundle of steel rods are stacked in a matrix to form a stacked body. Fig. 1 is a perspective view schematically showing an example of a laminate.

Here, the laminated body 2 will be described with reference to fig. 1.

First, a predetermined number of the bar steels 3 are bundled to form the bar bundles 4, and a plurality of the bar bundles 4 are stacked in a matrix. The number of the steel rods 3 constituting the steel rod bundle 4 may be different for each steel rod bundle 4. However, the number of the steel rods 3 constituting the steel rod bundle 4 is preferably fixed from the viewpoint of improving the work efficiency of the step of bundling the steel rods 3 to produce the steel rod bundle 4 and/or from the viewpoint of improving the stability of the stacked body 2 when a large number of the steel rod bundles 4 are stacked in a matrix. For example, the steel rods 3 are bundled into a fixed number (10 in the example of fig. 1) to form the steel rod bundle 4, and a large number of the steel rod bundles 4 are stacked in a matrix. In this case, in order to further stabilize the stacked body 2, it is more preferable to bundle the steel rods 3 in the steel rod bundles 4 in a uniform arrangement (3 to 4 to 3 in the example of fig. 1). In fig. 1, a binding band for binding the bar 3 is not shown.

Then, as the first layer of the laminated body 2, two or more bundles 4 (6 bundles in the example of fig. 1) of rod steels are arranged in parallel and laid flat with a space provided between the bundles 4. This gap is a passage through which a cooling mist described later passes through the interior of the stacked body 2, and a gap is provided between the bundle bars 4 adjacent to each other. However, the widths of the spaces are not necessarily the same.

The bundle bars 4 are arranged substantially in parallel in order to allow the cooling mist 5 to efficiently pass through the inside of a vertical gap (hereinafter, referred to as a vertical gap) formed by the bundle bars 4 of the first layer and the bundle bars 4 of the second layer, which will be described later. The steel bar bundles 4 are preferably arranged strictly parallel, but even if not necessarily parallel, there is no problem as long as the cooling mist 5 can pass through. Thus, deviations within ± 10 ° are tolerated with respect to the average value of the direction of the bundle of bar steel 4. The deviation of the direction of the bundle of steel rods 4 is more preferably within ± 5 °. The term substantially parallel means that the deviation is within the above range with respect to the average value of the directions of the steel bar bundles 4.

In order to prevent the bar 3 in the bundle of bar steels 4 from contacting the ground surface of the place where the bar is placed and causing a flaw, it is preferable to provide a mount 1 on the bottom surface and place the bundle of bar steels 4 on the mount 1.

Next, as a second layer of the laminated body 2, two or more bundles of rod steels 4 (6 bundles in the example of fig. 1) are arranged substantially at right angles to the bundles of rod steels 4 of the first layer, and are laid so as to provide spaces between the bundles of rod steels 4, thereby being stacked in a crisscross pattern.

When two or more bundles of rod steel 4 are arranged as the second layer of the stacked body 2 by a crane or the like, the reason why the direction of the bundle of rod steel 4 is substantially perpendicular to the bundle of rod steel 4 of the first layer of the stacked body 2 is to allow the cooling mist 5 to efficiently pass through the inside of the vertical gap. That is, if the longitudinal gap is formed in a quadrangular prism shape, the cooling mist 5 easily passes through. Therefore, the bundles of steel rods 4 of the second layer are preferably arranged exactly at right angles to the bundles of steel rods 4 of the first layer, but there is no problem, if at all, as long as the cooling mist 5 can pass through it, even if it is not necessarily at right angles. Thus, deviations within ± 10 ° are tolerated with respect to the average value of the direction of the bundle of bar steel 4. The deviation of the direction of the bundle of steel rods 4 is more preferably within ± 5 °. The substantially right angle means an average value of the deviation with respect to the direction of the steel bar bundle 4, and the deviation is within the range.

In the case where the laminated body 2 is stacked into 3 or more layers, the steel rod bundles 4 of the third and subsequent layers are sequentially stacked in a matrix in the same manner as the steel rod bundles 4 of the second layer, whereby the laminated body 2 shown in fig. 1 is formed.

The thus obtained laminated body 2 was sprayed with a cooling mist to cool the rod steel bundle 4. Here, an example of the cooling mist blowing device 8 of the present invention is shown in a perspective view in fig. 2. The ejection of the cooling mist is described with reference to fig. 3 and 4.

The blowing device 8 shown in fig. 2 is a device in which a plurality of mist nozzles 6 are arranged around or on the front surface of an axial flow fan 7. The blowing device 8 may have a blower 7, and the cooling mist can be blown from the mist nozzle 6 to the stacked body 2 by the air flow generated by the blower 7. In fig. 2, a hose for supplying cooling water to the mist nozzle 6 is not shown.

Although not shown, the following configuration may be adopted: a high-pressure air nozzle is used as the blower 5 to blow the cooling mist from the mist nozzle 6 toward the laminate 2. Alternatively, a two fluid nozzle of air and water may be used.

Although not shown, the blowing device 8 includes a control unit that controls the average particle diameter of the water droplets of the cooling mist blown into the vertical gap to be within a predetermined range. The control unit may blow the cooling mist from the mist nozzle 6 into a vertical gap formed by the first layer of the steel bar bundle and the second layer of the steel bar bundle immediately above the first layer in the vertical gap from below the first layer. The control unit may also control other functions of the blowing device 8. The control Unit is not particularly limited, and may be an information Processing device such as a computer having a CPU (Central Processing Unit).

As shown in fig. 3 and 4, the cooling mist 5 is ejected from below toward above into a gap in the longitudinal direction (i.e., the direction perpendicular to the floor surface of the installation site) formed by the mutually intersecting steel bar bundles 4 in the stacked body 2. Specifically, the cooling mist 5 is ejected from a mist generating device 6 (for example, a mist nozzle or the like) disposed below the first layer of the stacked body 2. Hereinafter, an example using a mist nozzle as an example of the mist generating device 6 will be described. In fig. 3 and 4, a hose for supplying the cooling water to the mist nozzle 6 is not shown.

In the present invention, the upward direction also includes a direction within a range of ± 10 degrees with respect to the vertical direction. Preferably within a range of ± 5 degrees.

The cooling mist 5 sprayed upward from the mist nozzle 6 is likely to rise inside the vertical gap due to the synergistic effect of the ascending air current generated by the atmosphere being heated by the high-temperature rod steel bundle 4 and the spray air current sprayed together with the cooling mist 5 from the mist nozzle 6. That is, since the cooling mist 5 is sprayed upward from below, the cooling mist 5 smoothly passes through the inside of the stacked body 2, and the entire stacked body 2 can be efficiently cooled.

Further, a blower 7 (see fig. 4) is preferably disposed below the mist nozzle 6 to blow the cooling mist 5 upward in the vertical gap. The bundle of bar steels 4 (i.e., the bar steels 3) can be cooled more efficiently by the ascending air current generated by the blower 7. In particular, when the bundle of steel rods is gradually cooled and the rising flow of air generated by heating the atmosphere is small, the effect of the blower 7 is large. Preferably, the air is blown from the blower 7 at a wind speed of 0.5m/sec or more and 5m/sec or less. If the flow rate is less than 0.5m/s, the cooling effect by the updraft generated by the blower 7 is small, and if the flow rate is more than 5m/sec, the amount of mist passing through the laminated body 2 before evaporation increases, and not only does the cooling efficiency decrease, but also the cooling mist scatters to other places and the surroundings may be wetted with water. The structure of the blower 7 is not particularly limited, and conventionally known units (for example, air nozzles and the like) are used. Alternatively, a two-fluid nozzle in which the mist nozzle 6 and the blower 7 are integrated may be used. The wind speed of the airflow can be measured by a known anemometer.

The water droplets of the cooling mist 5 sprayed to the longitudinal gap are evaporated by heat exchange with the bundle 4 of bar steel, i.e., the bar steel 3. Therefore, it is not necessary to provide a facility (e.g., a water tank tower) for collecting the water droplets and a facility (e.g., a cooling tower, a pipe, etc.) for circulating the water droplets as cooling water. When scale (for example, rust) is generated on the surface of the steel rod 3 by spraying the cooling mist, the steel rod bundle 4 is collected from the stacked body 2, the bundle is released (hereinafter, referred to as unbundling), and the steel rod 3 is taken out, and then the scale is removed and conveyed to a subsequent process (for example, processing and inspection). The means for unbundling and descaling the bundle of rod steels 4 is not particularly limited, and conventionally known techniques are used.

The smaller the average particle diameter of the water droplets of the cooling mist 5, the less heat is required for evaporation, and therefore evaporation is easy. However, if the average particle size is less than 20 μm, the water droplets of the cooling mist may evaporate before reaching the central portion after entering the interior of the laminate 2 together with the air flow, and thus it may be difficult to cool the entire laminate 2.

On the other hand, the larger the average particle size is, the more the heat amount required for evaporation increases, and the time required for cooling can be shortened. However, if the average particle size exceeds 300 μm, water droplets remain after the entire laminate 2 is cooled, and therefore, it is necessary to provide a facility for collecting water droplets and a facility for recycling water droplets as cooling water, and maintenance of complicated facilities requires a lot of labor. In addition, since water droplets are large, it is difficult to catch air flow, and it is difficult to cool the entire laminate 2. Therefore, the average particle diameter of the water droplets of the cooling mist is set to 300 μm or less. More preferably in the range of 20 to 120 μm, and if it is in this range, the cooling mist easily gets over the upper part of the stacked body by the airflow, the cooling efficiency is improved, and the floor of the place where the bar 3 is placed after cooling is not excessively wetted, and the workability is improved. When the average particle diameter of the water droplets is large, the cooling capacity is increased, and therefore, the time required to cool the steel bar to a desired temperature can be shortened, but the wet of the floor surface of the place where the steel bar 3 is placed after cooling is likely to remain. On the other hand, when the average particle diameter of the water droplets is small, the floor surface of the place where the cooled bar 3 is placed is easily dried, but the cooling capacity is small, so that the time required to cool the bar to a desired temperature becomes long. Therefore, in the case of carrying out the present invention, the average particle size of the water droplets may be selected within the range of 20 to 120 μm in consideration of the balance between the time required for cooling and the allowance of the degree of wetting of the floor surface of the place where the water droplets are placed after cooling. The method for controlling the particle size of the water droplets of the cooling mist is not particularly limited, and any known method may be used as long as a mist nozzle designed to generate a cooling mist having a desired particle size is used. The control unit (not shown) causes the mist nozzle 6 to blow a cooling mist of water droplets having a predetermined average particle diameter toward the stacked body 2.

In the present invention, in order to obtain water droplets having a desired average particle size, a mist nozzle designed and manufactured to obtain a mist of water droplets having a predetermined particle size on the premise of a predetermined amount of water, a predetermined water pressure, or the like is used.

That is, in the present invention, the average particle diameter (sauter average particle diameter) of the water droplets of the cooling mist is 300 μm or less means that the cooling mist is sprayed from a mist nozzle designed and manufactured so as to obtain the cooling mist composed of water droplets having an average particle diameter (sauter average particle diameter) of 300 μm or less.

When the metallurgical phase transformation of the steel bar 3 occurs due to the cooling by spraying the cooling mist as described above, problems such as deformation (for example, warping, bending, etc.) of the steel bar 3 and changes in mechanical properties of the steel bar 3 occur, and the progress of the subsequent process may be hindered. Therefore, it is preferable to spray the cooling mist after the metallurgical phase transformation of the steel bar 3 is completed.

When the length of each side of the longitudinal gap is less than 0.1m, the updraft accompanying the cooling mist 5 may be disturbed, and the cooling efficiency may be lowered. The area of the longitudinal gap is less than 0.04m²In this case, the updraft accompanying the cooling mist 5 may be obstructed, and the cooling efficiency may be reduced. Therefore, it is preferable that the length of each side of the longitudinal gap is 0.1m or more and the area of the longitudinal gap is 0.04m²The above.

I.e. if the length to each side is less than 0.1m, the longitudinal gap or area is less than 0.04m²When the cooling mist is sprayed to the vertical gap(s), the cooling mist may spread horizontally and obstruct the updraft in the stacked body 2.

When the number of the longitudinal gaps in the stacked body 2 is 3 or less, the entire stacked body 2 may not be uniformly cooled, and a long time may be required for cooling a portion having low cooling efficiency. On the other hand, in order to provide a vertical gap of 17 or more, the stack 2 has to be increased, and thus a large area may be required as a place to place the stack 2. Therefore, the number of the longitudinal gaps is preferably 4 to 16.

The longitudinal gaps in the stacked body 2 need not be provided on both sides of all the rod bundles 4 (i.e., on both sides in the width direction for each rod bundle 4), but from the viewpoint of uniformly cooling the rod bundles 4, it is preferable to provide a longitudinal gap for each rod bundle 4. If a longitudinal gap is present on at least one side of the bundle of steel rods 4, a more efficient cooling can be achieved than if a bundle of steel rods 4 not adjacent to the longitudinal gap is present. Therefore, it is more preferable that the two bundles of rod steels 4 be adjacent to each other with a longitudinal gap provided on both sides thereof (i.e., on one side of each bundle of rod steels 4).

Examples

In order to perform a cooling experiment using round bar steel as the bar steel, the bar steel bundles were stacked in a cross shape to form a laminated body. The laminate was formed by arranging 9 bundles of 17 bundled round bar steels in parallel at intervals to form a first layer, and the 9 bundles of bar steels, or later, were arranged at right angles to the bar steel bundles of the layer immediately below and stacked in a matrix to form a laminate of 10 layers in total. Therefore, the laminate is larger than the example shown in fig. 1. In this manner, 14 stacked bodies were formed.

Then, the cooling mist is ejected from the mist nozzle of the blowing device (see fig. 2) toward the longitudinal gap (see fig. 4). The spraying conditions of the cooling mist are shown in table 1. The total flow rate of cooling water sprayed as the cooling mist was 4L/min, and the water temperature was 30 ℃. In the case of using the blower, an air nozzle (see fig. 5) is disposed below the mist nozzle, and the air is ejected into the vertical gap at a wind speed of 5 m/sec.

The round bar steel is a carbon steel for machine structure containing 0.42-0.48 mass% of carbon (C), and has a diameter of 55mm and a length of 7 m. The temperature of the round bar steel at the time of completion of the stacking was 350 ℃, which is a temperature at which no metallurgical phase transformation occurred even when cooling was performed from this state.

While the laminated body was cooled, the time required for the maximum temperature of the round bar steel to fall to 50 ℃ was measured. The maximum temperature of the round bar steel was measured from above using a two-dimensional radiation thermometer, and was measured by detecting the maximum temperature in the measurement range. The results are shown in table 1 as cooling times. The atmospheric temperature of the place where the laminate was placed was 34 ℃.

[ Table 1]

The invention examples 1 to 11 in table 1 are examples of cooling experiments in which the particle size of the cooling mist, the size of the vertical gap, and the presence or absence of the use of the blower were combined in various ways, and the cooling time was within the range of 29 to 48 hours. In invention examples 2, 5, 6, and 8 in which the average particle diameter of the cooling mist was 60 μm, wetting of the place where the laminate was placed was not observed after completion of cooling. In invention examples 1, 3, 4 and 7 in which the average particle diameter of the cooling mist was 120 μm, although wetting of the place was caused, it was not necessary to discharge the accumulated water from the place.

In addition, in invention examples 1 to 11, although the scale was generated on a part of the round bar steel after the blowing of the cooling mist was stopped, the scale could be easily removed by the shot blasting method. In addition, no deformation (e.g., warpage, bending, etc.) of the round bar steel was observed.

On the other hand, comparative example 1 is an example in which the laminate was cooled slowly by heat dissipation into the atmosphere without blowing the cooling mist. Therefore, it took 91 hours for the maximum temperature of the round bar steel to fall to 50 ℃, which was significantly increased as compared with the invention examples 1 to 8.

Comparative example 2 is an example in which a stacked body was formed so that the steel bar bundles were in contact with each other without providing a longitudinal gap, and cooling mist (average particle diameter of 60 μm) was sprayed from a mist nozzle. In this example, it took 85 hours for the maximum temperature of the round bar steel to fall to 50 ℃, which was significantly increased as compared with the invention examples 1 to 8.

In comparative example 3, the average particle size of the cooling mist was set to 400 μm, and the cooling was performed from the vertical gap of the laminate. In this example, the sprayed cooling mist did not evaporate, and the floor surface of the place where the cooling mist was sprayed was heavily wet, and therefore the cooling experiment of the laminate was terminated.

After the cooling test described above was completed, arbitrary bundles of rod steels were collected from the laminated bodies of invention examples 1 to 11 and comparative examples 1 to 3, and the bundles were unbundled to take out one round rod steel, and the microstructure was observed with a microscope, and all the steel were ferrite-pearlite structures, and no abnormal structure was observed.

In addition, although the example of cooling round bar steel (i.e., bar steel having a circular cross section) is shown here, the object of the present invention is not limited to round bar steel, and may be applied to cooling square bar steel (i.e., bar steel having a polygonal cross section such as a rectangular cross section).

Claims (17)

1. A cooling mist blowing device for blowing cooling mist from a vertical gap formed by a first layer of steel bar bundles and a second layer of steel bar bundles immediately above the first layer of steel bar bundles among vertical gaps formed by crossing the steel bar bundles in a laminate of two or more layers, the laminate being formed by: the method for manufacturing a steel bar bundle includes the steps of bundling steel bars which are conveyed to a cooling bed after hot rolling is completed and are cut into a predetermined length after being discharged from the cooling bed to form the steel bar bundle, laying the two or more steel bar bundles substantially parallel to each other at an interval to form the first layer, laying the two or more steel bar bundles substantially perpendicular to the steel bar bundle of the first layer at an interval to form the second layer, and stacking the second layer and the third layer, and the subsequent steel bar bundles in a cross shape, as necessary,

the blowing device includes:

a mist nozzle that generates the cooling mist; and

and a control unit for controlling the average particle diameter of water droplets of the cooling mist blown onto the laminate to 300 [ mu ] m or less.

2. A cooling mist blowing device for blowing cooling mist from a vertical gap formed by a first layer of steel bar bundles and a second layer of steel bar bundles immediately above the first layer of steel bar bundles among vertical gaps formed by crossing the steel bar bundles in a laminate of two or more layers, the laminate being formed by: the method for manufacturing a steel bar bundle includes bundling a fixed number of steel bars, which are conveyed to a cooling bed after hot rolling is completed and are cut into a predetermined length after being discharged from the cooling bed, to form the steel bar bundle, laying the two or more steel bar bundles substantially parallel to each other at an interval to form the first layer, then laying the two or more steel bar bundles substantially perpendicular to the steel bar bundle of the first layer at an interval to form the second layer, and stacking the second layer and the third layer, and the subsequent layers, if necessary, the steel bar bundles in a cross shape,

the blowing device includes:

a mist nozzle that generates the cooling mist; and

and a control unit for controlling the average particle diameter of water droplets of the cooling mist blown onto the laminate to 300 [ mu ] m or less.

3. The cooling mist blowing device according to claim 1 or 2,

the cooling device is provided with a blower for generating an air flow for blowing the cooling mist from the mist nozzle to the laminated body.

4. The cooling mist blowing device according to claim 1 or 2,

the control unit causes the mist nozzle to spray the cooling mist from below the first layer to above the first layer.

5. The cooling mist blowing device according to claim 3,

the control unit causes the mist nozzle to spray the cooling mist from below the first layer to above the first layer.

6. The cooling mist blowing device according to claim 1 or 2,

the control unit controls the average particle diameter to be within a range of 20 to 120 [ mu ] m.

7. The cooling mist blowing device according to claim 3,

the control unit controls the average particle diameter to be within a range of 20 to 120 [ mu ] m.

8. The cooling mist blowing device according to claim 4,

the control unit controls the average particle diameter to be within a range of 20 to 120 [ mu ] m.

9. The cooling mist blowing device according to claim 5,

the control unit controls the average particle diameter to be within a range of 20 to 120 [ mu ] m.

10. The cooling mist blowing device according to claim 1 or 2,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

11. The cooling mist blowing device according to claim 3,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

12. The cooling mist blowing device according to claim 4,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

13. The cooling mist blowing device according to claim 5,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

14. The cooling mist blowing device according to claim 6,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

15. The cooling mist blowing device according to claim 7,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

16. The cooling mist blowing device according to claim 8,

is arranged in the laminated bodyHas 4-16 sides each having a length of 0.1m or more and an area of 0.04m²The above-described longitudinal gap.

17. The cooling mist blowing device according to claim 9,

the length of each side of 4-16 positions in the laminated body is more than 0.1m, and the area of each side is 0.04m²The above-described longitudinal gap.

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