METHOD OF HEAT TRANSFER AND ASSOCIATED DEVICE

Abstract

A method of heat transfer wherein a flat metal product having a broad face and a temperature upper to 400° C. is put in contact with a fluidized bed of solid particles, the solid particles having a direction of circulation (D), wherein the flat metal product is put in contact with the solid particles so that its broad face is parallel to the direction (D) of circulation of the solid particles and wherein a gas is injected so that the solid particles be in a bubbling regime, the solid particles capturing the heat released by the metal product and transferring the captured heat to a transfer medium. An associated device is also provided.

Claims

1-24. (canceled)

25. A method of heat transfer comprising: putting a flat metal product having a broad face and a temperature above 400° C. in contact with a fluidized bed of solid particles, the solid particles having a direction of circulation, so that the broad face is parallel to the direction of circulation of the solid particles; and injecting a gas so the solid particles are in a bubbling regime, the solid particles capturing heat released by the metal product and transferring the captured heat to a transfer medium.

26. The method as recited in claim 25 wherein the transfer medium is water.

27. The method as recited in claim 25 wherein the transfer medium is molten salts.

28. The method as recited in claim 26 wherein the water is used to produce steam.

29. The method as recited in claim 28 wherein the method is performed within a plant having a steam network and the produced steam is injected in said steam network.

30. The method as recited in claim 25 wherein the flat metal product is a slab or a plate.

31. The method as recited in claim 25 wherein the metal product is a steel product.

32. The method as recited in claim 25 wherein the solid particles have a heat capacity comprised between 500 and 2000 J/kg/K.

33. The method as recited in claim 25 wherein a density of the solid particles in the fluidized bed is comprised between 1400 and 4000 kg/m.sup.3.

34. The method as recited in claim 25 wherein the solid particles are made of alumina, SiC or steel slag.

35. The method as recited in claim 25 wherein the solid particles have an average size comprised between 30 and 300 μm.

36. The method as recited in claim 25 wherein an injection flow rate of the gas is controlled so as to monitor the cooling path of the metal product.

37. The method as recited in claim 25 wherein the gas is injected at a velocity between 5 and 30 cm/s.

38. The method as recited in claim 25 wherein the gas is air.

39. The method as recited in claim 25 wherein the metal product is a slab and the slab is placed on a support within the fluidized bed so that an edge of the slab is parallel to the floor.

40. The method as recited in claim 25 wherein metal product includes scale particles on the broad face or another surface, the scale particles being removed by the solid particles and the removed scale particles being regularly extracted from the fluidized bed.

41. The method as recited in claim 25 wherein the transfer medium contains nanoparticles.

42. The method as recited in claim 25 wherein the metal product is cooled from 800 to 400° C. in less than 60 minutes.

43. A device for heat transfer comprising: a chamber including a fluidized bed of solid particles, the solid particles capturing the heat released by a flat metal product having a broad face and a temperature above 400° C., the solid particles circulating along a circulation direction; a gas injector to inject gas within the chamber; a heat exchanger having a circulating transfer medium, the heat exchanger being in contact with the fluidized bed so that the solid particles transfer the captured heat to the transfer medium; and a support to support the flat metal product so that the broad face of the flat metal product is parallel to the circulation direction of the solid particles.

44. The device as recited in claim 43 wherein the transfer medium circulating within the heat exchanger is water.

45. The device as recited in claim 43 further comprising a device for extracting scale particles.

46. The device as recited in claim 45 wherein the device for extracting scale particles is a movable metallic grid.

47. The device as recited in claim 43 wherein the heat exchanger includes a first pipe to bring the transfer medium to the heat exchanger, a second pipe to recover the transfer medium at the exit of the chamber, and a third pipe, connected to the at least first pipe and to the second pipe, the third pipe being in contact with the fluidized bed of solid particles.

48. The device as recited in claim 47 wherein the at least one second pipe is connected to a steam production unit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0038] The invention will be better understood upon reading the description which follows, given with reference to the following appended figures:

[0039] FIG. 1 illustrates a slab;

[0040] FIG. 2 illustrates an embodiment of device to perform a heat transfer method according to the invention.

[0041] FIG. 3 illustrates different fluidization regimes;

[0042] FIG. 4 is curve simulating the thermal behavior of the surfaces and of the center of a slab with a method according to prior art and according to the invention;

[0043] FIG. 5 is a curve simulating the vertical displacement of a slab surface with a method according to the invention and to the prior art and its image representation.

DETAILED DESCRIPTION

[0044] In FIG. 1 is illustrated a slab 3, which is an example of a flat metal product. Said slab 3 has a parallelepipedal shape and comprises a top 3a and a bottom broad face, two small faces 3b and two edges 3c. The broad faces define the width W and the length L of the slab, said width W being usually comprised between 700 and 2 500 mm, the length L between 5 000 and 15 000 mm and the thickness T of the slab is usually comprised between 150 and 350 mm. More generally, a flat product can be defined as a parallelepiped wherein the smallest dimension (e.g. the thickness T) is negligible compared to the others (e.g. the length L), for example the smallest dimension being at least smaller than the biggest dimension of a factor 15. The broad faces of the parallelepiped are the faces which do not include the smallest dimension. Another example of a flat product is a plate or heavy plate.

[0045] Those flat products are usually semi-finished products, which means that they will be subjected to further manufacturing steps before being sold. For those subsequent steps it is important that the product is exempt of defects and notably that its flatness is guaranteed. For example, if a slab has a vertical bending of few millimeters it may raise difficulties during its further rolling or even make it impossible to roll which would imply the discarding of said slab.

[0046] In FIG. 2 is illustrated a device 1 to perform a heat transfer method according to the invention. This device 1 comprises a chamber 2 wherein hot flat metal products, such as slabs 3, are placed. The chamber 2 may be a closed chamber with a closable opening through which hot flat metal products may be conveyed, but it could also have an open roof or any configuration suitable for hot flat metal products conveying. Hot flat metal products 3 may be conveyed inside the chamber 2 by a rolling conveyor or maybe placed inside the chamber 2 by pick up means, such as cranes or any suitable pick up means. The chamber 2 is preferentially able to receive more than one flat product 3.

[0047] The chamber 2 contains solid particles and comprises gas injection means 4, gas being injected to fluidize the solid particles and create a fluidized bed of solid particles 5 in a bubbling regime, the solid fluidized particles circulating along a circulation direction (D). The hot flat metal products 3 are placed into the chamber 2 on support means so that their broad face 3a (see FIG. 1) is parallel to the direction (D) of circulation of the fluidized particles. In a preferred embodiment, the direction (D) is vertical and the slab 3 is placed on the support along its edge 3c so that its broad face 3a is parallel to the vertical direction. This allows not only promotion of heat transfer efficiency but also the avoidance of deformation of the product. The hot flat metal products have a temperature above 400° C. when placed into the chamber 2 and are for example slabs or plates and may be made of steel.

[0048] As illustrated in FIG. 3 there are several regimes of fluidization. Fluidization is the operation by which solid particles are transformed into a fluidlike state through suspension in a gas or a liquid. Depending on the fluid velocity, behavior of the particles is different. In gas-solid systems as the one of the invention, with an increase in flow velocity beyond minimum fluidization, large instabilities with bubbling and channeling of gases are observed. At higher velocities, agitation becomes more violent and the movement of solids become more vigorous. In addition, the bed does not expand much beyond its volume at minimum fluidization. At this stage the fluidized bed is in a bubbling regime, which is the required regime for the invention in order to have a good circulation of the solid particles and a homogeneous temperature of the fluidized bed. Gas velocity to be applied to get a given regime depends on several parameters like the kind of gas used, the size and density of the particles or the size of the chamber 2. This can be easily managed by a person skilled in the art.

[0049] The gas can be nitrogen or an inert gas such as argon or helium and in a preferred embodiment, air. It is preferably injected at a velocity between 5 and 30 cm/s which requires a low ventilation power and so a reduced energy consumption. In a preferred embodiment the injection flow rate of gas is controlled to monitor the cooling rate of the hot metal products 3. This may be advantageous for metal products whose quality is impacted by cooling rate, such as steel, but also be advantageous for the plant to regulate production.

[0050] The solid particles preferentially have a heat capacity comprised between 500 and 2000 J/Kg/K. Their density is preferentially comprised between 1400 and 4000 kg/m.sup.3. They maybe ceramic particles such as SiC, Alumina or steel slag. They may be made of glass or any other solid materials stable up to 1000° C. They preferably have a size comprised between 30 and 300 μm. These particles are preferably inert to prevent any reaction with the hot metal product 3.

[0051] The device 1 further comprises at least one heat exchanger 6 wherein a transfer medium is circulating, the heat exchanger being in contact with the fluidized bed 5. This heat exchanger may be composed, as illustrated in FIG. 1, of a first pipe 61 wherein a cool transfer medium 10 is circulating so as to bring it to the heat exchanger, a second pipe 62 wherein heated transfer medium 11 is recovered and third pipes 63 going connecting the first pipe 61 and the second pipe 62 and going through the chamber 2 and the fluidized bed 5 wherein the cool transfer medium 11 from the first pipe 61 is heated. With this device 1 the hot metal products 3 are immersed into the fluidized bed 5 of solid particles, solid particles which are then able to capture the heat released by the hot metal products 3. This allows a homogeneous cooling of the metal product, as all parts of the metal product are in contact with the fluidized solid particles. The solid particles are kept in motion by the injection of gas by the injection means 4 and come in contact with the heat exchanger 6 where they release the captured heat to the transfer medium circulating within. The flow rate of transfer medium inside the heat exchanger can be regulated to control the cooling rate, indeed the more medium is circulating inside the heat exchanger, the more heat is released from the solid particles.

[0052] In a preferred embodiment the transfer medium 10 circulating in the heat exchanger is pressurized water which, once heated by the heat released by the fluidized solid particles, is turned into steam 11. Pressurized water may have an absolute pressure between 1 and 30 Bar. Pressurized water may then be turned into steam by a flash drum 7 or any other suitable steam production equipment. Preferentially the water remains liquid inside the heat exchanger. The produced steam 11 may then be reused within the metal production plant by injection within the plant steam network, for hydrogen production for example or for RH vacuum degassers or CO.sub.2 gas separation units in the case of a steel plant. Having both steam reuse plant and metal product manufacturing plant within the same network of plant allows to improve the overall energy efficiency of said network.

[0053] The transfer medium 10 circulating in the heat exchanger may also be air or molten salts having preferably a phase change between 400 and 800° C. which allow to store the capture heat. The transfer medium 10 may comprises nanoparticles to promote heat transfer.

[0054] In a further embodiment the metal product 3 may comprise scale particles on its surfaces. By chemical or physical interaction with the solid fluidized particles, those scale particles may be removed from the metal product 3 and drop down at the bottom of the fluidized bed. In such a case the equipment 1 is provided with a scale removal device, such as a removable metallic grid shown solely schematically as G to frequently remove the scale particles from the fluidized bed.

[0055] With the method according to the invention metal products may be cooled down from 800° C. to 400° C. in less than 60 minutes.

[0056] The method according to the invention may be performed at the exit of a casting plant or at the exit of a levelling or rolling stand.

[0057] The method according to the invention allows a fast and homogeneous cooling of the metal product while recovering at least 90% of the heat released by the metal products without deformation of said product. Moreover, the device according to the invention is quite compact and can be adapted to the available space. As air tightness is not required it does not require a big investment nor a high level of maintenance to remain efficient.

EXAMPLES

Heat Recovery

[0058] A simulation was performed to evaluate the amount of heat which could be recovered from a steel slab with a method according to the invention.

[0059] In the method according to the invention, four slabs made of a commercial low carbon steel grade and having each a weight of 23 tons are placed in an equipment comprising solid particles of silicon carbide with a density of 320 kg/m.sup.3 and a Sauter diameter of 50 μm, those particles being fluidized in a bubbling regime thanks to the injection of air at 5 cm/s.

[0060] A heat exchanger as the one illustrated in FIG. 1 using water as fluid was used for the simulation. 2 scenarios were considered, one with an initial slab temperature of 800° C. and a cooling up to 400° C. and a 2.sup.nd scenario with an initial temperature of 550° C. and a final one of 250° C. For both scenario energy recovered, and steam quantity and pressure produced were evaluated. Results are presented in table 1.

TABLE-US-00001 TABLE 1 Residency Energy Steam Steam T.sub.ini T.sub.final time of recovered produced pressure (° C.) (° C.) the slabs (GJ/slab) (t/slab) (Bar) 800 400 35 min 7.41 2.25 26 550 250 35 min 4.50 1.385 7
Steam pressure is not the same in both scenarios because as the initial temperature of the slabs are not the same, the water from the heat exchangers is not heated at the same temperature.
According to the simulation, almost 95% of the heat released by the slab could be captured thanks to the method according to the invention.

Product Impact

[0061] A simulation was performed to evaluate the deformation and the thermal impact of a cooling method according to prior art and according to the invention.

[0062] In both scenarios A and B, a slab made of a commercial low carbon steel grade and having a length L of 10 m, a width W of 1 m and a thickness T of 0.25 m, is placed in an equipment comprising solid particles of silicon carbide with a density of 320 kg/m.sup.3 and a Sauter diameter of 50 μm, those particles being fluidized in a bubbling regime thanks to the injection of air at 5 cm/s and circulating vertically, the bottom of the chamber being the horizontal direction.

[0063] A heat exchanger as the one illustrated in FIG. 2 using water as fluid was used for the simulation. In both scenario initial slab temperature is of 800° C. and it is cooled up to 400° C. In scenario A the slab is placed in the fluidized bed so that one of its broad face lay down on the support means, its broad faces being thus perpendicular to the direction of circulation of the fluidized particles while in the scenario B it is placed on one of its edges, its broad faces being thus parallel to the direction of circulation of the fluidized particles.

[0064] For both scenarios, the temperature evolution of slab at different depths within the thickness T and the deformation of said slab are simulated and illustrated respectively in FIGS. 4 and 5.

[0065] In FIG. 4 is represented the evolution of temperature with time of one point taken on the top broad face, slab center and bottom broad face.

[0066] It is clear from the simulation that the bottom and the top broad face don't follow the same thermal path, contrary to what happens with a method according to the invention (both curves are superposed, only one is visible).

[0067] This an impact on the product, as can be seen on FIG. 5. This figure represents first the curve of displacement in the vertical direction along the length of the product when cooling with a method according to prior art and a method according to the invention. In the two other pictures this displacement is represented directly on the product and we can see that when using a method according to prior art there is a clear bending of the product which won't come back to its initial flatness.

[0068] The method according to the invention allows thus capturing the heat released by the hot flat metal product without detrimental impact on the product and notably without involving a deformation of said product.