ITTO20111023A1 - GLASS OVEN PROVIDED WITH A HEAT EXCHANGER GROUP - Google Patents

Description

DESCRIPTION

â € œGLASS OVEN FITTED WITH A HEAT EXCHANGER GROUPâ €

The present invention relates to a glass oven provided with a heat exchanger unit.

As is known, continuous glass ovens work with temperatures of the order of 1500-1600 ° C and are equipped with heat exchangers to pre-heat the combustion air by means of the heat possessed by the outgoing fumes from the combustion chamber of the furnace.

Normally, to pre-heat the combustion air to temperatures of about 1200-1300 ° C, regenerative heat exchangers are used, which include at least one pair of regeneration chambers made of refractory material and having respective upper openings that communicate with the combustion chamber of the furnace. These ovens are also referred to as â € œ chamber ovensâ €. If the two chambers in refractory material are placed at the rear, the oven is called â € œendportâ € or â € œfurnace with U flameâ €; if several chambers are arranged on the sides of the oven, the latter is called â € œsideportâ €.

As regards operation, the flow of combustion air from an inlet of the exchanger passes into one of the regeneration chambers and finally enters the combustion chamber of the furnace; at the same time, the fumes leave the combustion chamber, pass into the other regeneration chamber, where they release heat, and leave an outlet of the exchanger. A system of valves is provided to reverse the flow of combustion air and the flow of fumes between the two regeneration chambers with cycles of specific duration (typically about 20 minutes), so that the heat accumulated in the regeneration chamber where the fumes is released to the combustion air which passes during the next cycle.

There is a growing need to lower the polluting emissions of fumes, in particular nitrogen oxides, which are characteristic of high temperature combustion as in the case of glass. For this purpose, the aim is to create reducing conditions in the combustion chamber by introducing a quantity of combustion air lower than that foreseen by the stoichiometric ratio. At the same time, to limit the formation of carbon oxides and unburnt products, the combustion must be completed at a later stage. In this way, a large part of the combustion is developed in reducing conditions in a first stage, with a main flow of combustion air, and combustion is completed in a second stage, with a secondary flow of combustion air commonly called `` afterburning air ''. € or â € œ staging airâ €.

In known post-combustion systems, the post-combustion air is taken from the external environment and therefore has a relatively low temperature. Using such systems, the amount of heat released to the fumes in the second stage would be relatively low, and it would take a relatively long time and a relatively large amount of air to complete the post-combustion.

The object of the present invention is that of realizing a glass furnace equipped with a heat exchanger unit, which allows the above mentioned drawbacks to be solved in a simple and economical way.

According to the present invention, a glass furnace is provided provided with a heat exchanger assembly as defined in claim 1.

The invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 is a schematic and partial plan view of a preferred embodiment of the glass furnace provided with a heat exchanger assembly according to the present invention; And

Figure 2 illustrates a variant of the glass furnace of Figure 1.

In Figure 1, 1 indicates a glass furnace (schematically illustrated), which comprises a combustion chamber 2 (partially illustrated) fed by fuel gas or fuel oil in a known way not described in detail.

The glass kiln 1 also comprises a heat exchanger unit adapted to heat a flow of air 3 which enters through an inlet 4 from the external environment, at a temperature of about 25 ° C. The heat to heat the air flow 3 is released by a flue gas flow 5 that comes out of the combustion chamber 2.

The heat exchanger assembly comprises a regenerative type heat exchanger 10, which in turn comprises:

- two regeneration chambers 11, made of refractory material, having respective upper openings 12 which are distinct from each other and which communicate with the combustion chamber 2 through respective ducts, called turrets 13 and made of refractory material;

- an outlet 14, which is connected to the lower part of the chambers 11 by means of respective separate ducts 15 and selectively communicates with the chambers 11 to allow the flow of fumes 5 to flow out;

- an inlet 16, which is connected to both ducts 15 by respective separate pipes 17 and selectively communicates with the chambers 11 to convey a flow of combustion air 18; And

- a set of reversing valves 19a, 19b (schematically illustrated), which are arranged in the pipes 17 and, respectively, in the pipes 15 (in an intermediate position between the outlet 14 and the outlet of the pipes 17 in the pipes 15 ).

The valves 19a, 19b are controlled by a control and command unit 20 (schematically illustrated) in an automatic way, according to a strategy not described in detail, to be switched in a synchronized manner and to reverse the flow of combustion air 18 and the flow of fumes 5 between chambers 11 with cycles of specific duration (for example, of 20 minutes).

The valves 19b of the ducts 15 can comprise respective movable bulkheads or gate valves (not shown), which, when in a closed position, are in contact with the fumes, on one side, and with heated air, on the other side. .

Any bulkheads are internally cooled by air, for example air drawn from the outside air at room temperature; or each valve 19b can be constituted by a pair of bulkheads or gate valves, which are movable together and define a gap between them when they are in the closed position. This cavity, if the thermal regimes require it, can receive cooling air (for example air drawn from the external environment) as a result of a depression naturally present in the cavity itself.

Still with reference to Figure 1, the chambers 11 house respective bundles of thermal storage elements 22, of a known type and not described in detail, which accumulate heat during the cycle in which the relative chamber 11 is crossed by the flow of fumes 5 , and during the subsequent cycle they release the accumulated heat to the combustion air flow 18 which passes into said chamber 11 in the opposite direction before entering the combustion chamber 2.

The heat exchanger unit also comprises a heat exchanger 25 of the recovery type, preferably made of metal material, operating continuously, i.e. without inversion of flow between the fumes and the air, and arranged in series, upstream of the exchanger 10 considering the forward direction of the combustion air flow 18.

The exchanger 25 comprises two passages 26 and 27. The passage 27 receives the flue gas flow 5 from an inlet 30 coinciding with the outlet 14 and conveys the flue gas flow 5 towards an outlet 31 which communicates with a chimney (not illustrated), preferably through the interposition of a filtering system (not illustrated), in order to discharge the fumes into the environment. The passage 26 conveys the flow of air 3 from the inlet 4 towards an outlet 28 which communicates with the inlet 16 through a pipe 29. The passage 26 comprises two air spaces arranged around respective vertical pipes, which are part of the passage 27: the air and the fumes flow in countercurrent and exchange heat through the metal walls of the vertical pipes that separate the passages 26,27.

Preferably, the pipe 29 has a branch defined by a pipe 35, thanks to which it is possible to bleed heated air 36 from the air flow 3. The heated air 36 is â € œcleanâ € that is, it is conveyed in ducts distinct from those of the fumes and can be used for different purposes, for example for district heating, to preheat the fuel to be sent to the combustion chamber 2 and / or the material to be melted (this material is defined by raw materials, or by a mixture of raw materials and glass cullet to be recycled).

The flow rate of tapped heated air 36 is regulated by a valve 37 (schematically illustrated) arranged in the pipe 35 and controlled by the control unit 20 as a function of memorized parameters and signals supplied by sensors (not shown), so that the flow of combustion air 18 remaining and entering the exchanger 10 has the theoretical flow rate necessary to obtain a certain thermal power, and / or a certain temperature, and / or a certain stoichiometric ratio with the fuel in the combustion chamber.

According to variants not illustrated, the exchanger 25 is made up of two or more recovery stages arranged in series, and possibly a tapping of heated air is provided between these stages.

In use, the fumes have a temperature of about 1500 ° C at the mouths 12, a temperature of 650-1050 ° C at the outlet 14 / inlet 30, and about 200 ° C at the outlet 31; and the air has a temperature of 300-750 ° C at outlet 28 / inlet 16, and about 1250 ° C at the outlets 12.

The roof towers 13, selectively, can receive a post-combustion air flow 38 to obtain a post-combustion in the outgoing fumes, after the combustion air flow 18 has been burned with the fuel under reducing conditions in the combustion chamber 2 .

According to the invention, the afterburner air flow 38 is formed by air that has been heated by the heat exchanger assembly of the glass furnace 1, so the temperature of the afterburner air is significantly higher. at room temperature.

In the embodiment of Figure 1, the post-combustion air is derived from a point upstream of the chambers 11, that is, it is defined by the air that has been heated by the exchanger 25. In particular, the air after combustion is derived through a duct 39, whose inlet communicates with the inlet 16 and the outlet 28. In other words, the duct 39 is a derivation that draws post-combustion air from the air that It was pre-heated by the entire exchanger 25.

The duct 39 is divided into two branches 40, which respectively terminate in the roof towers 13 and are provided with respective valves 19c (schematically illustrated) controlled by the control unit 20 in a synchronized manner with the valves 19a and 19b to open / close the branches 40 selectively and let the post-combustion air flow 38 flow into the flue 13 where the fumes pass, while the passage of air to the other flue 13 is blocked, where the combustion air flow 18 flows instead.

When the combustion air flow 18 and the flue gas flow 5 between the chambers 11 are reversed, the valves 19c are also switched (the one that was open becomes closed, and the one that was closed becomes open), so as to change the fan 13 where to cause the post-combustion.

Preferably, one or more regulating valves are provided to vary the flow rate of the post-combustion air flow 38. Conveniently, the valves 19c are configured in such a way as to perform not only the interception function, but also this flow regulation function. , varying its degree of opening in response to the control unit command 20.

In the embodiment of Figure 1, the post-combustion air is â € œcleanâ €, ie it has not come into contact with the fumes, so its composition can be determined.

According to a variant not shown, the exchanger 25 consists of several recovery stages arranged in series, and the inlet of the duct 39 communicates with an intermediate area of the passage 26 between these stages.

Figure 2 shows a variant whose components are indicated where possible by the same reference numbers as in Figure 1. Unlike Figure 1, the heat exchanger assembly could consist only of the exchanger 10, that is, without the recovery exchanger 25. The two towers 13 communicate with each other through a duct 42, preferably made of ceramic material.

The tower 13 in which the combustion air flows naturally operates at a higher pressure than that in the tower 13 in which the fumes flow. Therefore, a part of the combustion air can naturally be tapped through the duct 42, before reaching the combustion chamber 2, in response to the pressure difference between the two roof fans 13, therefore without the need to operate any shut-off valve.

Preferably, a regulation valve 43 made of ceramic material is in any case provided in the duct 42, in order to calibrate the flow rate of the post-combustion air 38 arriving from the adjacent tower 13.

The post-combustion air flow 38 is adequately conveyed by the chosen shapes by the duct 42, which is specially sized so as to guarantee the flow rate according to the needs. For example, if you think you are working in the combustion chamber in limited reducing conditions, a small amount of combustion air is diverted to the opposite fan, conveying most of it towards the combustion chamber for primary combustion. Vice versa, if more pronounced reducing conditions are required, the quota sent directly to the flue gas tower is increased, removing it from that foreseen for primary combustion.

The plant in figure 1 shows the application of post-combustion to a furnace equipped with a hybrid regenerative / recuperative heat recovery system, while the variant in figure 2 is also applicable to a traditional furnace of the only type regenerative.

In this variant, the post-combustion air is â € œdirectedâ € from the passage in the chambers 11, but reaches a much higher temperature (about 1250 ° C). Furthermore, the solution is relatively more compact and has fewer components than the embodiment of figure 1.

From the above, it is evident that the glass oven 1 is able to reduce the pollution of the fumes from nitrogen oxides by generating reducing conditions in the combustion chamber 2 and causing a post-combustion in the fumes exiting through the roof towers 13.

The heat caused by the post-combustion raises the temperature of the fumes, which then transfer this heat to the combustion air (and therefore to the post-combustion air) through the heat exchanger unit.

The post-combustion air, being heated, has a much higher temperature than that of the external environment, so the post-combustion can easily reach a high efficiency and be completed in a short time and with a quantity of air limited. At the same time, no additional heating systems are required, in addition to the heat exchanger unit already normally provided in the glass furnace 1.

Finally, it appears evident from the foregoing that modifications and variations may be made to the glass furnace 1 described that do not go beyond the scope of the present invention, as defined by the attached claims.

In particular, the recuperative type exchanger could have constructive characteristics different from those shown by way of example. Furthermore, the pipes 17 could flow directly into the chambers 11 in parallel with the pipes 15.

Furthermore, the post-combustion air could be introduced into the roof towers 13 in a position other than that schematically indicated, for example through a duct that crosses the vault or roof of the roof towers 13.

Claims (1)

CLAIMS 1.- Glass oven (1) comprising: - a combustion chamber (2); - a heat exchanger unit adapted to pre-heat combustion air by means of the heat of the fumes produced in the said combustion chamber (2); said group comprising a first heat exchanger (10), which is of the regenerative type and comprises: a) at least two regeneration chambers (11) communicating with said combustion chamber (2) through respective towers (13); b) inversion valve means (19a, 19b) controllable so as to reverse a flow of combustion air (18) and a flow of fumes (5) between the said regeneration chambers (11) with cycles of predetermined duration; characterized in that it comprises conveying means (39; 42) terminating in said towers (13) for introducing post-combustion air (38); said conveying means (39; 42) deriving said post-combustion air from combustion air which has been pre-heated by said heat exchanger unit. 2.- Glass furnace according to Claim 1, characterized in that said conveying means are provided with valves for regulating the flow rate. 3. A glass furnace according to Claim 1 or 2, characterized in that said conveying means comprise a first duct (42) which connects said towers (13). 4.- Glass furnace according to Claim 1 or 2, characterized in that said heat exchanger assembly comprises a second heat exchanger (25), which is of the recovery type and is arranged upstream of said first heat exchanger. heat (10); said conveying means comprising a second duct (39), which derives said post-combustion air from a point upstream of said regeneration chambers (11) and which divides into two branches (40); said branches (40) ending respectively in said towers (13) and being provided with respective shut-off valves (19c); said shut-off valves (19c) being controlled in a synchronized manner with said inversion valve means (19a, 19b) to selectively open / close said branches (40) and introduce said post-combustion air into the fumes exiting from said chamber combustion (2). 5.- Glass furnace according to Claim 4, characterized in that said shut-off valves also define respective valves for regulating the flow rate. 6.- Glass furnace according to Claim 4 or 5, characterized in that said second heat exchanger (25) comprises a combustion air outlet (28) connected to a combustion air inlet (16) of said first heat exchanger (10) and communicating with an inlet of said second conduit (39).