FR2549589A3 - High-temperature fume heat recuperator - Google Patents

Abstract

This recuperator, particularly for a reheating furnace for metallurgical products comprises a pipe (vein) 1 for the circulation of hot fumes and a pipe (vein) 2a, 2b for the circulation of a cold fluid, the two pipes (veins) being separated by a heat-exchange wall 5; according to the invention, in the fume pipe (vein) 1 is placed a body 6' possessing a surface having radiating properties and substantially free of thermal bridges with the exchange wall 5. This body 6' has the shape of a cone whose apex faces upstream of the fume pipe (vein) 1. Alternatively, the body has the shape of one or more panels arranged in diametrical planes in the fume pipe (vein) 1, or the shape of a helical strip coaxial with the fume pipe (vein) 1.

Description

HIGH TEMPERATURE SMOKE RECOVERY
The invention relates to a high temperature fume recuperator, in particular for a furnace for reheating steel products, such as steel slabs. The recuperator considered is of the type comprising a vein for the circulation of hot fumes to be cooled and a vein for the circulation of a cold fluid to be heated, the two veins being separated by a heat exchange wall.

 The ovens that equip rolling mill installations for flat products (band or heavy gauge trains) are mass tools and large consumers of energy. To fix the idea, a strip train producing 4 million tonnes of steel per year generally comprises 3 to 4 of these ovens, each of which consumes approximately 40,000 to 50,000 t.e.p. (tonnes of oil equivalent) of gas or heavy fuel oil per year.

 The steel slabs are reheated there before rolling at high temperatures (of the order of 12,000) and the fumes leaving the combustion chamber are themselves at temperatures of the order of 10,000C. Part of the thermal energy of these fumes is however recycled via an exchanger (or recuperator) placed on the flue pipe and used to preheat the combustion air sent to the burners. Current recuperators can induce fuel savings of the order of 1000 to 5000 toe. per oven and per year.

The technologies of recuperators currently used can be divided into three families
- "ceramic" recuperators, consisting of refractory stacks, admit fumes reaching 14000C, but are handicapped in their performance and in their operation by the constraint of a vacuum operation (air fan located between the recuperator and the oven ). These recuperators are being abandoned;
- the metallic radiators, which equip most French slab ovens, consist of a large smoke evacuation pipe and an external concentric pipe, the air passing through the annular space. smoked at temperatures up to 11000C, but their current yields are less than 30% despite their imposing dimensions (heights of 11 in the order of 30m);
- tubular convection recuperators are made up of thin metal tubes crossing the flue pipe and supplied with air at high speed. The holding of the tubes limits the temperature of the fumes at the inlet to around 9000C; this type of device is therefore sometimes placed in series with a radiation recuperator ("mixed recuperator"). In practice, convection recuperators always lead to satisfactory recovery yields (40%), or even very good (70%) when they are provided with a large exchange surface.

 To improve the recovery on current ovens, it is not enough to replace their radiant heaters with convection devices. Indeed, the smoke temperatures practiced often exceed 10000C and the protection of the convective tubes cannot be ensured satisfactorily by the mere dilution of the fumes: this would lead to losing on the exchange efficiency or oversizing the device.

 In practice, it is often necessary to apply the mixed solution, consisting in protecting the convection recuperator by a first radiation part.

 However, this solution leads to a high investment (of the order of 10 y the price of a new oven) and to large-scale work (immobilization of an oven for at least 1 month) which cannot be carried out on battery ovens only over time (over a period of 5 years for example).

 I1 then appears particularly interesting to improve the current radiation devices. This is the object of the invention.

 This object is achieved thanks to a body placed in the smoke stream, having a surface having radiating properties, and substantially free of thermal bridges with the exchange wall. This body then serves as a radiative relay.

 The inventor has been able to show that this arrangement is all the more effective when the high temperature of the body is used exclusively for transfers by radiation, and not by conduction, to the exchange wall.

 Advantageously, the body is suspended in the smoke stream, which is vertical.

 According to a first embodiment, the body takes the form of one or more panels arranged in diametrical planes of the smoke stream.

 According to a second embodiment, the body assumes the shape of a cone, the apex of which is turned upstream of the smoke stream, in the direction of circulation of the smoke.

 According to a third embodiment, the body takes the form of a helical band coaxial with the smoke stream.

The invention will be better understood on reading the following description of the three preferred embodiments. Reference will be made to the appended drawings on which
- Figure 1 is a cross section of a recuperator equipped with the first embodiment of the radiative body;
- Figures 2 and 3 are vertical diametrical sections of a recuperator equipped respectively with the second and third embodiments of the radiative body.

 Figures 1 to 3 show the vertical cylindrical stream 1 of smoke circulation, concentrically surrounded by the annular stream 2 of air circulation. The vein 2 can if necessary be made up of two sections 2a, 2b in which the air circulates respectively in co-current and against the current of the fumes from the vein 1. The cold air is introduced by the conduits 3 placed in end, and recovered after reheating, by intermediate pipes 4.

 The fumes circulate from bottom to top of the stream 2, into which they enter at temperatures of the order of 10000C to 12000, coming from the combustion chamber of a slab reheating furnace (not shown).

 The veins 2 and 3 are separated by the cylindrical heat exchange wall 5.

 In FIG. 1, the radiating body 6 is a cross-piece constituted by two perpendicular metal plates, placed in diametrical planes of the vein 1, and therefore not impeding the passage of the fumes. The body is preferably suspended in the vein by a suspension not shown. It can also be maintained on the exchange wall 5 by thermally insulating mechanical connections, the main thing being to minimize the thermal bridges between the body 6 and said wall 5, in order to allow the plate to reach a high temperature. increasing the radiation emitted (which increases with the fourth power of temperature).

 According to another aspect of the invention, an attempt is also made to improve the share (admittedly not preponderant) of thermal exchanges by convection, by giving the body interposed in the smoke stream the additional function of restoring in the vein a regime of transient flow. Indeed, the inventor has discovered that the length of establishment of the turbulent regime in the smoke stream, which moreover depends on the exact geometry of the inlet of the stream, is several times the diameter of the stream, but is however generally less than the length thereof. However, the convective exchange is higher in the zone of establishment of the turbulent regime than in the zone of established turbulent regime. This is why, according to the invention, it is advantageous to interpose in the vein 1 a body 6 ' - (fig. 2) having the shape of an inverted cone whose radiating conical surface increases the radiative exchanges while the transverse maltre-couple of the cone 6 'imposes on the fumes a modification of their flow regime favorable to convective exchanges. As in the previous embodiment, the cone-turbulator 6 ′ is substantially free of thermal bridges with the wall 5.

 The embodiment of FIG. 3 combines the advantages of two previous embodiments: very large radiating surface, and permanent maintenance of the transient smoke flow regime.

The body 6 "for this purpose takes the form of a helical band, coaxial with the smoke stream 1, and of a width slightly less than the radius of a circular section of this vein. Here again, the body 6" can be suspended in the vein or fixed to the wall by thermally insulating fixings.

Claims (5)

 1) Heat recovery of smoke at high temperatures, in particular for furnace for heating steel products, of the type comprising a stream (1) for the circulation of hot fumes to be cooled and a stream (2) for the circulation of a cold fluid 9 reheat, the two veins being separated by a heat exchange wall (5), characterized in that it comprises a body (6,6 ', 6 ") placed in the smoke vein (1), having a surface having radiant properties, and substantially free of thermal bridges with the exchange wall (5).  2) recuperator according to claim 1, characterized in that the body (6,6 ', 6 ") is suspended in the smoke stream (1), which is vertical.  3) A recuperator according to claim 1 or 2, characterized in that the body (6) takes the form of one or more panels arranged in diametrical planes of the smoke stream (1).  4) recuperator according to claim 1 or 2, characterized in that the body (6 ') assumes the shape of a cone whose top is turned upstream of the smoke stream (1), in the direction of circulation fumes.  5) A recuperator according to claim 1 or 2, characterized in that the body (6 ") takes the form of a helical strip coaxial with the smoke stream (1).