NL7909283A - METHOD AND DEVICE FOR COOLING FOR METAL TREATMENT - Google Patents

Description

% * '. VO 8904

Method and device for cooling for the treatment of metals.

The invention relates to a method and an apparatus for the continuous treatment of metals, in particular metal workpieces or treated belts, in particular plates.

In the many metal treatment processes, after a suitable heating cycle, cooling is used, the rate of which determines the metallurgical final structure of the product. This cooling should be controllable depending on the dimensions of the workpieces or treated belts as well as the hourly production of the device to achieve a constant cooling rate.

Various techniques have been proposed to meet these requirements. Among these known techniques can be mentioned: blowing with air, blowing an air-atomized liquid suspension, and sprinkling by a liquid jet, etc.

These techniques have their drawbacks: - blowing with only air even in large quantity is unsuitable to ensure the high exchange coefficients? - methods of blowing with an air-atomized liquid suspension, although smooth and efficient, generally require significant carrier gas pressures from the standpoint of thermal exchanges and are therefore not economical; the systems of sprinkling by a jet of liquid are very efficient with regard to cooling, but they cannot operate in a wide range of exchange coefficients.

In the present invention, it is proposed to ensure the intended cooling characteristics, namely high exchange coefficients and control over an important range of these coefficients.

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The method according to the invention is characterized in that a conical liquid jet is introduced into a gas jet of low pressure at a precisely selected location, which is thrown at great speed against the products to be cooled, the injection being effected such that the liquid particles are dispersed in the entire volume of the gas jet to form a mist therein which is thrown on the products to be cooled.

According to an inventive feature, the gas pressure, in particular of the air, is less than 0.15 bar, which offers the advantage that the gas jet can be obtained by using a centrifugal fan.

In the method according to the invention, the aeolian liquid jet is formed by droplets with a diameter of the order of 0.8 to 2 mm and injected into the gas jet by the latter and, under the influence of the frictional effect, into much finer droplets of the order of Crushed 0.05 to 0.2mm diameter. As mentioned above, the geometry of the injection is chosen such that the liquid particles dispersed in the gas jet form a mist inside the latter. This mist thrown on the products to be cooled brings the fine liquid particles into contact with the very hot walls of the product to be cooled, the temperature of which can reach 1100 ° C. The resulting evaporation absorbs the heat and appears from very intensive thermal exchanges.

According to the invention, large gas flows and relatively small liquid flows are used.

Preferably, the gas is charged with liquid in an amount generally equal to or less than 0.25 kg of liquid per 1 Nm 2 of gas. Within these limits and by modifying the liquid flow rate, thermal exchange coefficients varying in the ratio of 1 to 10 are obtained. Due to the low liquid contents, a good choice of gas flow rates allows total evaporation of the droplets. to obtain.

According to the invention, a change in the intensity of the cooling is obtained by changes in the liquid flow rate or in the gas flow rate or both at the same time.

The invention also relates to an apparatus for carrying out the above-described method. This device, which can be contained in a cooling zone of a device for continuously treating metallurgical products, comprises on either side of the product to be cooled, which circulates continuously, series of either pipes or gas blowers, containing adjusting means discharging the gas in the form of conical jets, each adjusting member being provided with a liquid injector, wherein the injection of the liquid into the gas jet is chosen such that an optimum breaking of the droplets emerging from said liquid jet is obtained.

According to the invention, the height of an injector relative to the adjusting member above which it is placed is equal to the diameter obtained by this adjusting member.

According to another feature of the invention, the blowing / perpendicular rows are positioned in the sense of displacement of the product to be cooled and the settings of the different rows are offset from one another.

According to the invention, said gas is air and the liquid is water.

Other features and advantages of the invention follow from the description below with reference to the drawing illustrating a non-limiting exemplary embodiment. In the drawing fig. 1 schematically shows in perspective a device according to the invention for cooling continuously successive plates and fig. 2 schematically an example of the

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-4— placement of an injector relative to its institution.

Referring to Figure 1, it is seen that the plate 1, moving in the direction indicated by the arrow, passes through the cooling section formed by a given number of sets of pipes, such as 2a, or cabinets such as 2b, in which a gas containing air> at low pressure is blown using, for example, a centrifugal fan (not shown). Of course, the cooling system consisting of the tubes or the cabinets 2 represents variants 10 which cannot exist simultaneously on a single device. These cabinets or tubes are arranged on either side of the plate 1. The tubes 2a and the cabinets 2b are provided with a number of adjusting members 3 through which the gas is delivered in the form of conical jets.

As can be seen from the drawing, each setting 3 is provided with an injector 4 for mechanical atomization of liquid, the feed of these injectors being effected through the collectors 5.

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The adjusting members 3 are arranged / surfaces parallel to the belt in rows perpendicular to the direction of movement of the plate to be cooled.

The adjusters of these rows are offset from each other as can be clearly seen in Figure 1 to ensure better cooling homogeneity across the width of the product to be treated here consisting of plate 1.

The mist obtained as indicated above by throwing the liquid particles into the entire volume of the gas jet is directed to the plate to be cooled.

The geometry of the injection of the liquid into the gas jet is determined such that an optimum breaking of the droplets emerging from the liquid jet is obtained. Referring to FIG. 2, it will be seen that the position of the injector 4 is determined by the distance h separating it from the setting 3 above which it is placed. According to the invention, this distance h is approximately equal to the diameter d caused by the setting 3, the ratio g · between this caused diameter and the actual diameter D of the setting 3 depending on the profile of this 5 setting.

The diameter d caused is a function of the atomizing angle α of the injector 4, which angle is generally in the vicinity of 30 °.

By way of non-limiting example, the other characteristic parameters of this device are the following:

Diameter D of the adjusting members: 30-100 mm

Pressure of blown gas (air): 200-1200 da Pa (2000-12000 N / m2) 5 2 15 Pressure of the liquid (water): 1-7.10 N / m

Liquid (water) flow per injector: 15-200 1 / h

Under the above conditions, it is possible with an apparatus according to the invention to obtain average thermal exchange coefficients between 100 and 2000 W / m2. ° C, which coefficients are adjustable in a ratio of 1 to 10 for a given device.

As examples of applications of the invention can be mentioned the cooling of belts or strong plates or of joints or billets.

7909283

Claims (9)

1. Method of cooling for the continuous treatment of metals, characterized in that a conical liquid jet is injected into a gas jet of low pressure at a carefully selected location, which is thrown at great speed on the products to be cooled, the injection is carried out such that the liquid particles are dispersed in the entire volume of the gas jet to form a mist therein, which. the products to be cooled are thrown. Method according to claim 1, characterized in that the pressure of the gas into which the liquid jet 2 is injected is less than 15000 Newton / m and preferably 2 2000-12000 Newton / m. 3. A method according to claims 1-2, characterized in that the gas is charged with liquid in an amount which is at most 0.25 kg of liquid per 1 Nm of gas. 4. Method according to claims 1-3, characterized in that the gas is air and the injected liquid water. 5. Apparatus for carrying out the method according to claims 1-4, included in a cooling zone of a continuous treatment device of metallurgical products, characterized in that they are arranged on either side of the surfaces of the continuously circulating product to be cooled in rows of tubes or boxes for blowing gas comprises those adjusting means which deliver the gas in the form of conical jets, each setting being provided with a liquid injector while the injection of the liquid 30 into the gas jet is chosen such that an optimum breaking of the liquid jet coming from the particles are obtained. 6. Device according to claim 5, characterized in that the height h of an injector relative to the setting above which it is placed is equal to the 3 3 2 8-3 V -7 diameter d caused by said adjustment. 7. Device as claimed in claims 5-6, characterized in that the blow adjusting members / plane are arranged parallel to the belt in rows perpendicular to the direction of displacement of the product to be cooled. Device according to claim 7, characterized in that the adjusting members of the different rows are offset from one another. 9. Device according to claims 5-8, characterized in that the injectors are of the mechanical type. 7909233