DE2140508C2 - Method and device for guiding the cooling air in a furnace - Google Patents

Description

35

The invention relates to a method and a device for guiding the cooling air in a combustion system with cooling grate for mineral granulates, with a split air flow through the hottest area of the cooling grate which partly comes directly from the atmosphere, partly from the entire area above the coldest Cooling grate section is removed.

A preferred field of application of the invention is the treatment of cement clinker. * s

In such systems, it is known to wholly or partially use the heated cooling air as secondary air for the Use the furnace burner.

All the cooling air is z. B. used in ovens that work according to the so-called wet process in which a cement paste is burned, which requires such an amount of heat that the necessary combustion air is essentially equal to the air blown into the cooling system.

In kilns of the type mentioned (DE-AS 14 08 990), which according to the dry process or semi-dry process work, only part of the cooling air is required, as this is where the heat requirement is essential is smaller. The excess cooling air is therefore exhaust air and must be blown into the atmosphere. There however, if it is dusty and has a relatively high temperature, this results in a not inconsiderable one Problems, especially considering the increasingly stringent environmental protection conditions. The dust that is carried along cannot practically be separated with electrostatic precipitators. For the deposition the temperature of the exhaust air is too high due to the usual hose or bag filters. One must therefore be proportionate expensive filters, e.g. B. use glass fiber fabric and the like. That are relatively fragile and therefore sensitive and still leave something to be desired in terms of temperature resistance.

However, there are also systems known that contain dedusting devices suitable for high temperatures, which work in the manner of cyclones. The efficiency and dedusting capacity of such devices however leave a lot to be desired.

It is also known to use gravel filters in which the air to be dedusted is passed through a bed of gravel flows. These filters are expensive and bulky, and their capacity is limited. Systems that at nominal throughput Deliver exhaust air with a given dust concentration, are practically not able to sudden overloads, e.g. B. in abnormal operating conditions of the furnace, such as sudden slipping of the clinker or in the case of operating errors, to process in which the amount of dust z. B. suddenly by the factor 5 or 10 increases.

Finally, systems are also known that have a gas recuperation circuit contain, through which the exhaust gas or the exhaust air to utilize the contained in it Heat is fed to a furnace or directly to a drying device. With such systems result the known problems regarding the coordination of the operation of the recuperation system with that of the Oven, especially when starting up when the recuperation system has to be shut down periodically.

The difficulties with regard to dedusting the exhaust air are extremely great, if not practically insoluble, in the new provisions, which require that the amount of dust per cubic meter under normal conditions (atmospheric pressure, 0 ^° C.) must not exceed 150 mg. Since the exhaust air is blown off into the atmosphere at a temperature of around 280 ° C, this means that it has practically twice the volume of air under normal conditions.

For example, a kiln operating according to the dry process with a throughput of 1500 tons per day per kilogram of clinker requires approximately 2.5 Nm ³ (cubic meters under normal conditions) of cooling air, that is approximately 150,000 NmVh. For the burner of the furnace, on the other hand, only about 0.9 Nm ³ per kilogram of clinker are required as secondary air, which corresponds to about 50,000 NmVh. This results in an excess of air of 100,000 NmVh or effectively 200,000 mVh, which must not contain more than 75 mg of dust per cubic meter.

In general, the cooling air contains, after it has flowed through the cooling grate, about 3 to 6 g of dust per cubic meter; Electrostatic precipitators are practically useless, cyclones are only able to reduce the dust content to about 300 to 400 mg / m ³ and gravel filters, which in themselves ensure adequate dedusting, are large, heavy and expensive ^{with a throughput of 2 × 10 5 mVh.}

Accordingly, the object of the invention is to provide a simple way of eliminating the dust removal problem to create, whereby neither the cooling of the fired goods, nor the processing of the in the Secondary air reaching the combustion system is to be impaired.

To solve this problem, the method according to the invention is characterized in that the middle A flow of cooling air passes through the area of the cooling grate and is constantly circulating within a circuit in which a heat exchanger is included.

With the achievement of optimal conditions in cooperation

In connection with the cooling and the secondary air treatment, according to the invention, any dust emission is an issue the atmosphere suppressed. This applies to normal operation, even under changing operating conditions. An atmosphere outlet for the circulated in the circuit can only be used for emergencies Cooling air can be provided.

A device with a particularly well suited for carrying out the method according to the invention Cooling grate and a device for extracting air from the atmosphere and from the entire area above the coldest cooling grate section and for conveying this split air flow through the hottest The area of the cooling grate is characterized by a fan for circulating a flow of cooling air through it a central cooling grate section within a circuit in which a heat exchanger is contained. As an advantageous development of this device, the invention provides a temperature sensor that is shown in an oven upstream of the cooling grate and controls the throughput of the fan via a controller.

The idea of the invention is explained below with reference to exemplary embodiments in conjunction with the drawing explained in more detail; it shows

1 shows a schematic, partially sectioned view of a device for carrying out the method according to the invention and

FIG. 2 is a schematic representation of part of FIG Device according to FIG. 1.

The system shown in Fig. 1 contains a rotary kiln 1 with burner 2 which opens into a cooling device 3.

The cooling device 3 includes a grate 5, which is divided into several sections 7, 8, 9 and 10, whose Number depends on the performance and dimensions of the cooling device. In each of the box-like Sections open to cooling air ducts, the openings of which are marked 11 (section 7), 12 (section 8), 13 and 14 (section 9) and 15 (section 10) are designated. All mouths are below the Grate 5

Fresh air from the atmosphere is blown in through the opening 11 by means of a fan 16. This air in practice has a temperature of around 20 ° C and penetrates the grate 5 in the hottest zone of the cooling device, where it is heated to about 950 "and exits that part of the cooling device that is connected to communicates with the outlet of the furnace 1 via an opening 17.

Fresh air is blown in by means of a fan 18 through the opening 15 in section 10 at the outlet of the cooling device in its coldest zone. This air is heated to a temperature of the order of 120 to 150.degree. C. and is sucked off through an opening 19 located in the upper part of this zone of the cooling device. The opening 19 is connected to a channel 20 which leads to a fan 21, which conveys the air sucked out of the section 10 of the cooling device through a channel 22 and the opening 12 into the section 8 of the cooling device. This relatively cool with about 120 to 150 ⁰ C air flows through the grate 5 is HEAT during the cooling of the clinker / i and flows through the opening 17 into the furnace 1, wherein it mixes with the air from the section. 7 The part of the cooling device located above section 9 has a collecting opening 23 at the top, to which a duct 24 is connected which leads to one or more fans 25, the outlet 26 of which leads via lines 266 and 26b to openings 13 and 14. A heat exchanger 4 operating as a cooler is arranged in the channel 24 upstream of the fan 25 in the direction of flow. The air, which after penetration of the goods to be cooled from section 9 of the cooling device at a temperature of z. B. about 350 ° C escapes, is continuously fed back in this way through the channel 24, the fan 25 and the lines 26, 26a, 26b

ίο thereby through the heat exchanger 4 to a temperature recooled in the order of 120 ° C, d. H. at such a low temperature that a flawless and continuous operation of the cooling device, in particular the drive of the grate 5, is guaranteed.

To the fans 21 and 25 against excessive wear caused by the air entrained in the intake air To protect dust, dedusting devices 28 to 29 are preferably inserted into the channels 20 and 24, preferably baffle plate separators or cyclones, which remove those dust particles that affect the blower are most dangerous, remove them without completely dedusting them.

The embodiment shown in Fig. 1 can be modified without leaving the scope of the invention exceed. So you can z. B. provide additional cooling sections and additional fans. An advantageous one A modification consists in doubling the recirculation circuit by opening the opening 23 several channels 24 are connected, each of which has a heat exchanger 4, fan 25 and connected as a cooler Contains lines 26 which open into openings corresponding to the openings 13 and 14.

In Fig. 2 is an embodiment of the heat exchanger 4 shown. In this heat exchanger, the hot and cold parts are completely separated. The hot part contains a tube bundle 27 in the illustrated embodiment, but others can of course also be used Use heat exchangers with separate channels and with any liquid or gaseous refrigerant, work like air. One can use a single coolant or several different coolants in different circulate in parallel circuits.

In the illustrated embodiment, cooling air from the environment is at a temperature of the order of magnitude of 20.degree. C. through a channel 30 into a chamber 31 through which the tube bundle 27 passes will; the air heated to a temperature of up to about 200 ° C. is sucked off by a fan 32 and promoted in a line 33.

The arrangement described has many advantages: Above all, no exhaust air gets into the atmosphere and you therefore does not need expensive and complex dedusting systems to meet the environmental protection requirements suffice. Because the air that enters the furnace 1 through the opening 17, and there as secondary combustion air serves, a mixture of the coming from section 7, about 950 ° C hot air and that from the section 8 coming, about 850 ° C hot air, you can see the temperature of the secondary combustion air and thus regulate the furnace temperature via the throughputs of the fans 16 and 21.

For this purpose, one or more temperature sensors 35 are arranged in the furnace 1 and in the opening 17, which are connected to a comparison and control arrangement 36, which the fans 16 and 21 via lines 37 or 38 controls.

You can also connect a branch 34 to the line 33 (Fig. 2), through which the burner 2 with

Primary air is fed, which on the one hand completely dust-free and on the other hand in the heat exchanger 4 to about 200 ° C is heated, which improves the thermal efficiency of the burner 2.

Another utilization or return of the amount of heat carried along by the air in the circuit 24 is very simple, since the air heated by this air in the line 33 is completely pure. Man can this air z. B. use as combustion air in drying ovens or for dry mills.

For safety reasons, a channel 39 is connected to the opening 19, which makes it possible, if necessary, to discharge part of the air from the interior of the cooling device 3 to the atmosphere. For the same Basically, you can connect the channel 22 via a line 40 with the Entlül'tungskanal 39 in order to -if some of the air conveyed by the fan 21 derive.

The invention is particularly suitable for cement kilns, but it is not limited thereto, but can be to a wide variety of systems are used which contain an oven for a cooling device, e.g. IJ. He /. Roasting systems, Lime kilns, pelletizing kilns, as well as continuously operating sintering and burning systems.

Of course, the invention can also be applied to systems that instead of that shown in FIG Vibrating grates contain a traveling grate or a rotating grate.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Method for guiding the cooling air in a furnace with a cooling grate for mineral granulates, in which a split air flow passes through the hottest area of the cooling grate, some of it directly taken from the atmosphere, partly from the entire area above the coldest cooling grate section is, characterized in that a cooling air flow through the central region of the cooling grate which is constantly circulated within a circuit in which a heat exchanger included 1st. 2. Apparatus for performing the method according to claim 1 with a cooling grate and a device for drawing in air from the atmosphere and from the entire area above the coldest Cooling grate section and for conveying this split air flow through the hottest area of the cooling grate, characterized by a fan (25) for circulating a flow of cooling air through a central one Cooling grate section (9) within a circuit (24, 26) in which a heat exchanger (4) is contained is. 3. Apparatus according to claim 2, characterized in that the upstream of the cooling grate (5) Oven (1) has a temperature sensor (35) that controls the throughputs of fans via a controller (36) (16 or 21) controls which fresh air in the hottest area (7) of the cooling grate (5) or cooling air in promote a less hot area (8).