DE10129000A1 - Firing furnace with cooling zone has motor-driven roller conveyor, distributors, and ventilation fan, - Google Patents

Abstract

The tiles (4)are conveyed by a motor-driven roller conveyor (3) At least two distributor media for the coolant are used for the ventilator fan - at l east one of which is beneath the roller conveyor and another above it. The axis of at least one distributor (11) runs parallel with the direction of the tiles' travel inside the oven.

Description

This invention relates to kilns for Kera micro tiles and especially the section for cooling of ceramic products, such as tiles, in End area of the furnace.

The known types of stoves, especially those for firing stoves used by ceramic tiles, have nearby a zone for cooling the kera at the outlet mikfliesen. This cooling zone consists in particular of at least three chambers, d. H. a first chamber, the be immediately behind the burning area of the stove takes place and is called rapid cooling, one second chamber, which is referred to as slow cooling and finally a third chamber, which is called Final cooling is called.  

The transport of the is carried out in this cooling zone Tiles in several parallel rows are arranged by means of a motor-driven roller lenbahn; the tiles are there from an ambient flows around the air flow, which from several nozzle sticks, de axis perpendicular to the transport direction of the tiles runs, is blown into the chamber.

These nozzle sticks are both above and below arranged half of the roller conveyor and are with several Provide holes that the airflow in the right Win the direction of transport of the tiles into the chamber blow in so that the larger areas of the tiles around be rinsed.

In the above-mentioned rapid cooling range, i.e. H. in the Zone of the furnace that is immediately after the kiln rich, it has been shown that Regu possible cooling medium flow (ambient air) Have the tiles flatness corrected.

The regulation of the volume flow of the cooling medium too works together with the usual nozzle sticks perfect for smaller tile formats, but is for large format tiles, that is tiles with a Size of more than 30 × 30 cm, not sufficient to correct any flatness errors.

This is largely due to the fact that the nozzle sticks mounted transversely to the transport movement  Space reasons can not be placed as close as would be required to have a sufficient nozzle density Direction of transport of the tiles.

In addition, the use of nozzle sticks enables the mounted across the tile transport direction, none differentiated cooling in the furnace cross section.

The object of this invention is to overcome the disadvantages the previous technology is affected by a ra tional, efficient and relatively inexpensive solution to avoid.

The invention fulfills the above-mentioned target set and other objectives thanks to a furnace in which the tile cooling zone, especially the Rapid cooling zone, equipped with a cooling system which, in addition to the usual first nozzle sticks for the distribution of the cooling medium, which is transverse to the flow direction of transport are mounted, at least still comprises a second distributor, the axis of which in Principle runs in the tile transport direction and their Nozzles are arranged so that the coolant flow to one of the larger tile areas is directed towards it.

This distribution device, at least one in front must be able to act, both under and over the Tiles arranged; the delivery of the coolant is through special flow restrictors (Venti le) regulated.  

In a preferred embodiment, this distribution device, at least one of which is present there are several distribution devices both under and also arranged above the tile transport device net.

The regulation of the flow of these two distributing conveyed cooling medium follows depending on the flatness errors that the tiles on Have oven exit.

The arrangement of these second distributors he it is possible to move the nozzles closer together, for example in a distance between 20 and 40 mm, which is what the cross-mounted nozzle sticks through the min The center distance of the nozzle sticks cannot be reached can.

This advantageously results in a more efficient action of the cooling medium on the tiles surface.

It also allows the arrangement of this second Ver sub-devices of the invention, the axis of which we considerably parallel to the tile transport direction running to realize a second big advantage namely the possibility of cooling the tiles along the cross section of the cooling zone of the furnace to dif allow references.  

A variant of the first embodiment of the inven According to the are in the rapid cooling zone the oven only the aforementioned second distribution device mentions, whereas the aforementioned first, transverse mon Distribution devices are missing.

The special characteristics of the invention are in the An called sayings.

In order to better clarify the structural and functional Characteristics of the invention is preferred below te embodiment described, a not be represents a restrictive example and in the as an attachment attached drawings is explained in more detail.

Fig. 1 shows a cross section of the cooling zone of the furnace according to the invention.

Fig. 2 shows the cross section II-II of Fig. 1.

Fig. 3 shows the cross section III-III of Fig. 1.

Fig. 4 shows a cross section of the cooling zone of the furnace according to a variant of the invention.

Fig. 5 shows the cross section VV of Fig. 4.

In the above-mentioned FIG. 1, 2 and 3 is a fast cooling zone of the furnace 1 illustrated with a tunnel 2 which is located immediately behind the combustion chamber of the furnace, which is not shown, since it is usual technique.

Through the furnace with the tunnel 2 runs a roller transport device 3 , which is known from the art and on the tiles 4 , which are arranged in several parallel rows, who transported the.

In the rapid cooling zone 1 are the system for cooling the tiles 4 , which comprises two rows 6 and 7 of conventional nozzle assemblies or distribution pipes or distribution devices 8 , the axis of which extends transversely to the direction of transport of the tiles 4 , and two rows 9 and 10 with Nozzle sticks or distribution pipes or Ver part devices 11 , the axis of which extends in the transport direction of the tiles 4 , each in the rapid cooling zone 1 .

In the description of the embodiment of the invention these distribution devices are in the form of conductors with a circular cross-section or tubes.

In particular, each of the rows 9 and 10 in the embodiment explained in the invention comprises two groups with three nozzle assemblies 11 which are arranged in the vicinity of the side walls 20 of the furnace 2 .

Each of the nozzle assemblies 8 and 11 has a plurality of partial nozzles 12 which are directed toward the tiles 4 which are to be cooled. With reference to FIG. 1, the nozzle assemblies 8 and 11 of the rows 6 and 9 are directed downwards in order to blow the cooling medium from above onto the tiles 4 , whereas the nozzle assemblies 8 and 11 have nozzles 12 which are directed upwards and blow the cooling medium (ambient air) onto the tiles 4 from above.

The distance between the nozzles 12 of the nozzle assemblies 8 and 11 should be between 20 and 40 mm if possible.

The nozzle assemblies 11 are connected to a collector 13 , a throttle valve 14 being seated between each nozzle assembly and the collector 13 . The collector 13 in turn communicates via a valve 15 which throttles the flow with a Ven tilator, not shown, which promotes the cooling medium, which is usually air at ambient temperature.

The nozzle assemblies 8 , on the other hand, are connected to a collector, not shown, which is supplied with cooling medium via a conventional conveyor device (fan), which, since it is known, is not shown, is supplied.

The operation of the invention is quite simple. The promotion of the cooling medium through the nozzle assemblies depending on the flatness defects that the Show tiles after cooling, regulated.  

The flow rate that emerges from certain nozzle assemblies 8 and 11 or from rows 6 , 7 , 9 and 10 can be regulated in this way depending on the type of geometric error of the tile.

For example, if the tiles are cool after cooling vex are arched down, the cooling effect is on the underside of the tiles increased so that the flatness error compensated.

In Figs. 4 and 5 a variant is represented to the first embodiment of the invention.

The figures mentioned show the rapid cooling area 20 of the furnace with tunnel 21 , through which an ordinary motor-driven roller conveyor 22 runs, which transports the tiles 23 . More specifically, the tiles 23 are arranged in parallel rows on the roller conveyor 22 .

In the rapid cooling zone 20 is the system for cooling the tiles 23 , which comprises two rows 24 and 25 of distributing devices 26 , each of which is arranged above or below the roller conveyor 22 .

In the illustrated embodiment of the invention, the distribution pipes or distribution devices 26 consist of a plurality of nozzle assemblies, the axis of which runs parallel to the tile transport direction, in the rapid cooling zone 20 of the oven.

Each of the two rows 24 and 25 is connected to a collector 27 which conveys the cooling medium, which is usually air at ambient temperature; an externally adjustable throttle device (valve) 28 , which throttles the cooling medium flow, sits between each nozzle assembly 26 and the above-mentioned collector 27 .

The collector 27 in turn communicates via a throttle valve 30 with an external line 29 which conveys the cooling medium.

The cooling medium is passed through a conventional fan, not shown, to the above-mentioned external line 29 and then to the nozzle assemblies 26 .

Each of the nozzle blocks 26 is connected to a plurality of nozzles 260 , which are arranged so that they direct the cooling medium flow in principle at right angles to the trans port direction of the tiles 23 , so that the two larger tile sides are washed around.

The operation of the variant of the invention is almost identical to the functionality already described the first embodiment of the invention; out of this For this reason, it is not described separately here.

It should be noted that the nozzle assemblies 8 , 11 and 26 in the embodiments of the invention described or explained in the drawings have a round cross section; but they can of course also be designed as lines with a round, but not with a square or rectangular cross-section.

Claims (6)

1. Cooling section of a furnace for firing ceramic tiles, through which a motor-driven roller conveyor for transporting the tiles runs, with a Ge fan fan for the cooling medium, with which at least two means for cooling medium distribution are provided, of which at least one is under The aforementioned motor-driven roller conveyor is located and is able to blow the cooling medium from below against the tile surface, and at least one other is located above the aforementioned motor-driven roller conveyor and is able to blow the cooling medium from above onto the tile surface, characterized That the axis of at least one of the two pre-named distributing devices ( 11 , 26 ) extends in parallel to the direction of transport ( 3 ) of the tiles ( 4 , 23 ) inside the furnace. 2. Cooling section according to claim 1, characterized in that each of the distribution devices ( 11 , 26 ), of which at least two must be present and which are arranged parallel to the transport direction ( 3 ) of the tiles ( 4 , 23 ) in the furnace interior, via a Throttle device (valve) ( 15 , 28 ), which it enables to regulate the cooling medium flow in order to differentiate the action of the medium in the cross section of the furnace cooling section, communicates with the blower fan for the cooling medium. 3. Cooling section according to claim 1, characterized in that each of the distributing devices ( 11 , 26 ) which are arranged parallel to the transport direction ( 3 ) of the tiles ( 4 , 23 ) in the interior of the furnace has a plurality of nozzles. 4. cooling section according to claim 3, characterized in that the nozzles have a center distance between 20 and 40 mm to have. 5. cooling section according to claim 1, characterized in that each of the distribution devices (11, 26) paral lel to the transport direction (3) of the tiles (4, 23) are arranged inside the furnace, two rows of nozzle assemblies (11, 26) has a circular cross-section. 6. Cooling section according to claim 1, characterized in that the distribution devices ( 11 , 26 ), which are arranged parallel to the transport direction ( 3 ) of the tiles ( 4 , 23 ) inside the furnace, are combined with distribution means, the axis of which is at right angles to the transport direction ( 3 ) the tiles ( 4 , 23 ) inside the furnace.