ITUB20155392A1 - Apparatus and method for recovering heat from exhaust fumes of a billet heating furnace - Google Patents

Description

"Apparatus and method of heat recovery from exhaust fumes of a furnace for heating billets"

The present invention relates to an apparatus for recovering heat from the exhaust fumes of a furnace for heating billets.

This apparatus can be advantageously used in the aluminum sector. A furnace for heating aluminum billets is known in which the heat of combustion fumes is used to preheat ambient air which is then used in the furnace itself as a comburent for combustion.

The furnace for heating billets is used to bring the same to an outlet of about 500 ° C to then allow them to be processed in a subsequent extruder. The temperature of the outgoing fumes is approximately 450-500 ° C.

The object of the present invention is to propose an apparatus and a method of heat recovery which allows to minimize the energy consumption for aluminum processing and to minimize the environmental impact of the release of fumes.

The specified technical task and the specified purposes are substantially achieved by an apparatus and a method for recovering heat from the exhaust fumes of a billet heating furnace comprising the technical characteristics set out in one or more of the appended claims.

Further characteristics and advantages of the present invention will become clearer from the indicative, and therefore non-limiting, description of an apparatus and a method for recovering heat from exhaust fumes of a billet furnace as illustrated in the accompanying drawings in which:

figure 1 shows a system comprising an apparatus according to the present invention;

- Figures 2 and 3 show a top view and a side view of an apparatus according to the present invention;

-figure 4 shows a view according to section A-A of the apparatus of figure 3; figure 4a shows an enlargement of figure 4;

figure 5 shows a sectional view of the apparatus according to the present invention;

figure 6 shows a succession of steps from left to right of a step of the method according to the present invention;

-figure 7 schematizes the path of a heat carrier gas within a portion of the apparatus according to the present invention.

In the accompanying figures, the reference number 1 indicates an apparatus for recovering heat from the exhaust fumes of a billet furnace.

The apparatus 1 includes a circuit 2 in which a heat carrier gas recirculates. Typically the heat carrier gas is air. The apparatus 1 comprises means 6 for moving the heat carrier gas which induce a forced circulation along the circuit 2. Typically the flow rate of the heat carrier gas is approximately 25,000 m <3> / h. The handling means 6 comprise for example a blade impeller, typically a centrifugal fan.

The circuit 2 in turn comprises a heat exchanger 21 in which the heat carrier gas is intended to be heated by the exhaust fumes. The heat exchanger 21 advantageously comprises a tube bundle exchanger. Conveniently, the heat carrier gas leaving the heat exchanger 21 is at a temperature between 200 ° C and 350 ° C.

The circuit 2 in turn comprises a preheater 22. The circuit 2 comprises a duct 24 downstream of the exchanger 21 which connects the exchanger 21 and the preheater 22. The circuit 2 also includes a duct 25 downstream of the preheater 22 which connects the preheater 22 and the exchanger 21.

Said preheater 22 in turn comprises a compartment 4 for the transit of the billets. The billets are then preheated along the transit compartment 4. The apparatus 1 comprises means 23 for advancing the billets along the preheater 22. In particular, the advancement means 23 allow the advancement of the billets along the compartment 4. The advancement means 23 include a "pilgrim step conveyor 230".

Conveniently, the conveyor 230 comprises a movable movement 232 with respect to a temporary support 233. The support 233 is conveniently fixed. Conveniently, the mover 232 is driven by at least one fluid-dynamic piston (driven by an operating liquid). The piston comprises an end hinged to the mover 232 and an end hinged to a fixed frame. The conveyor 230 and the support 233 can accommodate a plurality of billets 9 arranged side by side transversely with respect to the advancement of the conveyor 230.

The mover 232 can move between a raised configuration and a lowered configuration. In the raised configuration it is intended to support the billets, in the lowered configuration the temporary support 233 is intended to support the billets.

By passing from the raised configuration to the lowered configuration, the handler 232 transfers the billets to the temporary support 233. Passing from the lowered configuration to the raised configuration, the handler 232 picks up the billets from the support 233.

The handler 232 can also move back and forth along a direction of advancement of the billets along the compartment 22.

In the following, with reference to the method, the handling procedure of the conveyor 230 will be better described.

The compartment 4 comprises at least one entrance door 44 and an exit door 45. Conveniently, the entry door 44 is movable upwards to allow the entry of the billets. Conveniently, the exit door 45 is movable upwards to allow the output of the billets. Conveniently, the billets leaving the preheater are at a temperature of about 250 ° C.

The handler 232 in the raised configuration is sealed with the inlet door 44 and the outlet door 45. This allows you to avoid unwanted heat escapes.

The apparatus 1 also comprises a station 3 for feeding a billet to said billet advancement means 23 (see for example Figures 4 and 5).

In this regard, the feeding station 3 advantageously includes an actuator 30 movable between the top and the bottom (suitably vertically) between:

-a position for receiving a billet (for example Figure 4, 4a, 5); -a position for transferring the billet towards (preferably the) means 23 for advancing the billet (situation not illustrated).

In the transfer position, the actuator 30 is lowered with respect to the receiving position. Conveniently, it is substantially at the same height as the handler 232.

In the receiving position, the actuator 30 is placed at a greater height than the movement 232.

The feeding station 3 conveniently comprises a movable jaw 300 which picks up a billet by positioning it on the actuator 30 in the receiving position. The fact that in the receiving position the actuator 30 is raised allows to open the jaw 300 without the risk of interfering with a billet placed on the handler 232 (in fact the billets already present on the handler will be at a lower level).

The preheater 22 comprises diverging baffle means 41 for widening a flow of the heat carrier gas. For example, the deflector means 41 could comprise a truncated cone immersed in the flow of the heat carrier gas. Conveniently, the flow of the heat carrier gas laps both internally and externally the deflector means 41. In particular, the flow passes both internally and externally to the truncated cone.

The preheater 2 further comprises a plurality of outlets 42 for delivering the heat carrier gas. The dispensing mouths 42 (or at least a part of them) are superimposed, at least in a first configuration of the advancement means 23, with corresponding areas 231 for positioning the billets. The billets 9 are kept in the positioning zones 231 by concavities present in said advancement means 23. Preferably, in said first configuration of the advancement means 23, the dispensing mouths 42 are located above said positioning zones 231. Conveniently, the advancement means 23 remain stationary for a predetermined time period in the first configuration (ie they stop during the advancement).

At least one dispensing mouth 42 (suitably a plurality, preferably all the dispensing mouths 42) can comprise a convergent 421 and possibly a slot 422 located downstream of the convergent 421. The slot 422 is immediately downstream of the convergent 421. It defines a channel that develops along the outflow of the heat carrier gas for a length between 15 and 25 millimeters, preferably 20 millimeters. The distance between two opposite edges which define the slot 422 is suitably comprised between 8 and 13 millimeters, preferably 10 millimeters.

The plurality of mouths 42 are located downstream of the deflector means 41. Preferably, the preheater 2 comprises passages 43 for evacuating the heat-carrying gas which, with respect to said positioning zones 231, are at least partially in the opposite position to the delivery mouths 42 (at least in the first configuration of the advancement means 23).

The evacuation passages 43 lead into a chamber 5 inside the preheater 22. This chamber 5 can conveniently be located below the compartment 4.

The internal chamber 5 has at least one outlet 50. The circuit 2 comprises an evacuation duct 51 which extends adhering to a side wall of the compartment 4.

In the preheater 2 (and more generally in the apparatus 1) no flames are generated that produce heat by burning fuel.

The object of the present invention is also a system 10 comprising: -a furnace 11 for heating billets;

- a recovery apparatus 1 having one or more of the characteristics described above; in particular, the preheater 22 of the recovery apparatus 1 is placed upstream of the oven 11; the compartment 4 of the preheater is external and separate from the oven 11.

The system 10 can also comprise a billet extrusion station located downstream of the kiln 11.

Conveniently along the flue gas evacuation duct heat exchange means are placed which allow to heat the ambient air to be introduced into the burner mixed with the fuel (in order to use it as a comburent).

The object of the present invention is a method of recovering the heat of exhaust fumes from a furnace 11 for billets.

Conveniently, the method is implemented by an apparatus for recovering heat from the exhaust fumes of a billet furnace having one or more of the characteristics described above.

The method comprises the step of heating a heat carrier gas in a heat exchanger 21 using the exhaust fumes of the furnace 11 for billets 9. The method comprises a step of conveying the heat carrier gas inside a preheater 22 placed upstream of the furnace. 11 and suitable for the transit of the billets 9 to be pre-heated.

In the preheater 22 the heat carrier gas directly invests the billets 9.

In particular, the heat-carrying gas surrounds a plurality (preferably all) of the billets. This allows to optimize a homogeneous heat exchange with the billet 9.

The step of conveying the heat-carrying gas inside the preheater 22 can comprise the step of making the heat-carrying gas pass at least through deflector means 41 which allow a widening of the flow of the heat-carrying gas. Figure 7 schematically shows the outflow of the heat carrier gas inside the preheater 22. The isosceles triangles show the direction of outflow of the heat carrier gas.

The step of conveying the heat-carrying gas inside the preheater 22 may include the step of letting the heat-carrying gas flow through delivery outlets 42. The delivery outlets 42 are conveniently located downstream of said deflector means 41. The dispensing mouths 42 can lie along the same plane, advantageously horizontal.

The heat-carrying gas flows through the delivery mouths 42 at a speed of between 5 and 6 m / s.

The method further comprises the step of extracting the heat carrier gas from the preheater 22 returning it to the heat exchanger 21. The heat carrier gas recirculates along a closed path.

The method further comprises the step of evacuating the heat-carrying gas after it has hit the billets 9 by means of evacuation passages 43 having a converging structure 430. Conveniently, the heat-carrying gas touches the billets at 360 ° 9.

In a preferred operating mode, the billets 9 are stationed in a position in which the minimum distance between one of the billets 9 and the converging structure 430 is greater than or equal to 0.66 times the minimum distance between two side-by-side billets 9 present in the preheater 22.

Conveniently, the method comprises the step of positioning the billets 9 inside the preheater 22. This advantageously provides for them to be stationed in a first position at (suitably below) the dispensing mouths 42 so that the billets 9 are better invested from the heat carrier gas. Said first position of the billets 9 corresponds to a first configuration of the advancement means 23. The method comprises the step of advancing the billets 9 along the preheater 22. Conveniently this takes place by means of a conveyor 230 which is suitably of the "pilgrim's step" type. The billets are advanced along the preheater 22 from an inlet door 44 to an outlet door 45. The billets usually remain inside the compartment 4 of the preheater for a time comprised between 90 and 150 minutes, preferably 110-130 minutes.

Before placing the billets inside the preheater 22, the method comprises the step of loading at least one billet by means of a jaw 300 onto an actuator 30 which is in the raised position.

The method also includes the step of lowering the actuator 30 to position the billet towards (on) the conveyor 230.

Conveniently, the pilgrim step conveyor 230 comprises a handler 232 and a temporary support 233 for the billets 9. The conveyor 230 and the support 233 can accommodate a plurality of billets 9 arranged side by side with respect to the advancement of the conveyor 230.

With reference, by way of example, to Figure 6, the conveyor 230 implements the following procedure (typically in an iterative way):

removing an end billet from the mover 232;

- lowering the handler 232 so as to position the billets present on the handler 232 on the support 233;

- move the 232 handler back for a shorter length than the center distance between two billets 9 (typically the center distance between two billets is 270 millimeters, at least if the billets 9 have a diameter between 200 and 210 millimeters);

- moving the handler 232 upwards bringing the billets 9 placed on the support 233 into contact with said handler 232, this causing a transfer of the billets 9 from the support 233 to the handler 232, said transfer being accompanied by a rotation of the billets 9; this rotation improves the uniformity of heating of the billets;

- to advance the movement device 232; suitably this takes place until the billets placed on the handler 232 are on the vertical of the overlying delivery outlets 42.

The present invention achieves important advantages.

It allows to reduce the heat consumption of an oven located downstream of the preheater. This allows savings on energy consumption of up to 20% -30%.

Furthermore, by reducing the temperature of the fumes leaving the system, it is also possible to contain the environmental impact.

The apparatus for heat recovery from exhaust fumes of a billet furnace can also be applied to existing furnaces thus allowing maximum flexibility of application.

The invention thus conceived is susceptible of numerous modifications and variations, all falling within the scope of the inventive concept that characterizes it. Furthermore, all the details can be replaced by other technically equivalent elements. In practice, all the materials used, as well as the dimensions, may be any according to requirements.

Claims (10)

CLAIMS 1. Apparatus for recovering heat from exhaust fumes of a billet heating furnace comprising a circuit (2) in which a heat carrier gas recirculates, characterized in that the circuit (2) in turn comprises: -a heat exchanger (21) in which the heat carrier gas is intended to be heated by the exhaust fumes; -a preheater (22) comprising a compartment (4) for the transit of the billets; - means (23) for advancing the billets along the preheater (22). 2. Apparatus according to claim 1, characterized in that the advancing means (23) comprise a pilgrim step conveyor (230). 3. Apparatus according to claim 1 or 2, characterized in that it comprises a station (3) for feeding a billet to said billet feeding means (23); the power station (3) comprising an actuator (30) movable between the top and the bottom between: - a position for receiving a billet; -a position for transferring the billet to the billet advancing means (23); in the transfer position the actuator (30) being lowered with respect to the receiving position. 4. Apparatus according to any one of the preceding claims, characterized in that said preheater (22) comprises: diverging deflector means (41) for widening the flow of the heat carrier gas; -a plurality of outlets (42) for delivering the heat carrier gas superimposed, at least in a first configuration of the advancing means (23), with corresponding areas (231) for positioning the billets, said plurality of outlets (42) being located downstream deflector means (41); -passages (43) for evacuation of the heat-carrying gas which, with respect to said positioning areas (231), are in the opposite position to the delivery outlets (42). 5. Apparatus according to claim 4, characterized in that at least one of said dispensing mouths (42) comprises: - a convergent (421); -a crack (422) located downstream of the convergent (421). 6. Apparatus according to claim 4 or 5, characterized in that the evacuation passages (43) lead into a chamber (5) internal to the preheater (22), said internal chamber (5) having at least one outlet (50); the circuit (2) comprising an evacuation duct (51) which extends adhering to a side wall of the preheater (22). 7. System comprising: -a furnace (11) for billets; - a recovery apparatus (1) according to any one of claims 1 to 6; the preheater (22) of the recovery apparatus (1) being placed upstream of the oven (11); - a billet extrusion station located downstream of the furnace (11). 8. Method of heat recovery of exhaust fumes from a furnace (11) for billets characterized in that it comprises the steps of: - heating in a heat exchanger (21) a heat carrier gas with the exhaust fumes of the furnace (11) for heating billets (9); - conveying the heat carrier gas inside a preheater (22) placed upstream of the oven (11) and suitable for the transit of the billets (9) to be preheated, the heat carrier gas directly investing the billets (9) in the preheater (22); - extract the heat carrier gas from the preheater (22) returning it to the heat exchanger (21), called heat carrier gas by recirculating between the preheater (22) and the heat exchanger (21). 9. Method according to claim 8, characterized in that the step of conveying the heat carrier gas inside the preheater (22) comprises the step of allowing the heat carrier gas to flow through delivery openings (42) at a speed between 5 and 6 m / s; the method including the steps of: - placing the billets (9) inside the preheater (22) in a first position in correspondence with said delivery outlets (42) so that the billets (9) are hit by the heat carrier gas; in the first position the minimum distance between one of said billets (9) and said converging structure (430) is greater than or equal to 0.66 times the minimum distance between two billets (9) side by side present in the preheater (22) - evacuating the heat carrier gas after it has hit the billets (9) by means of evacuation passages (43) having a converging structure (430). Method according to claim 8 or 9, characterized by advancing the billets (9) along the preheater (22) by means of a pilgrim pitch conveyor (230) comprising a handler (232) and a temporary support (233) for the billets (9), said conveyor (230) and said support (233) being able to accommodate a plurality of billets (9) arranged side by side with respect to the advancement of the conveyor (230), said conveyor (230) implementing the following procedure: removing an end billet from the mover (232); - lower the handler (232) so as to position the billets present on the handler (232) on the support (233); - move the mover (232) back for a shorter length than the center distance between two billets (9); - move the handling unit (232) upwards bringing the billets (9) into contact with said handler (232), this causing a transfer of the billets (9) from the support (233) to the handler (232), said transfer being accompanied by a rotation of the billets (9); - advance the mover (232).