DE29506470U1 - Device for drying moldings, in particular roof tiles - Google Patents

Description

OJ DE-G 295 06 470.6

Note: Novokeram .., file: 220-64 er 04.07.1996

CHANGED DESCRIPTION

Device for drying'formings/

in particular roof tiles

The invention relates to a device for drying formations, in particular roof tiles, with the features in the preamble of the main claim.

Such a device is known from DE-A 30 49 162. In the dryer shown here, the external blowing device generates a central air flow that is guided around the housing of a drying chamber and enters the chamber interior through a large number of through holes on opposite sides of the drying chamber. The moldings are arranged on a dryer carriage in several layers on top of each other and in several rows next to each other. The dry air entering from the opposite side walls is thereby swirled and reaches the material to be dried in an uncontrolled manner. The blowing in from both sides also creates an air jam inside the chamber. DE-A 31 38 shows a similar design with the same disadvantages.

Perforated drying frames for roof tiles are known from AT-E 26 419 and DE-C 902 234. They are intended for use in a kiln. In both cases, the drying frames are intended to be laid in several layers

to stack them on top of each other. This means that the moldings cannot be blown directly and frontally onto their broad sides.

From DE-OS 38 40 264 a tunnel dryer with a continuous conveyor belt and a blowing device is known, which guides the drying air in a meandering manner over the material to be dried. The moldings lie on an air-permeable conveyor belt and are alternately

&iacgr;&ogr; blown above and below.-

Another device is known from US-C 4,439,929. The device shown is used specifically for drying hollow honeycomb bodies, in particular so-called catalysts. These moldings stand on a perforated sheet and are first dried in a dielectric dryer using alternating electric fields, with an air flow supplied from the side to prevent condensation phenomena. The moldings are then dried in a hot air blower dryer. The perforated sheets used serve primarily to allow the air flow to reach the hollow interior and the honeycombs of the molding. The perforated sheets have no further significance because the moldings can also lie across them, with the drying air then also being directed across the perforated sheets. The drying air should always flow through the hollow molding.

From DE-B-p 17 308 a D it is also known to dry hollow ceramic tubes standing on a grid and to blow a dry air flow through the grid into the tubes from below. Here too, the perforated sheet or grid only has the task of allowing the dry air to flow through the hollow molding.

From DE-A-39 38 682 it is known to dry ceramic moldings in a conditioned air stream. The humidity and temperature in the drying chamber or in the air stream are adjusted to the drying behavior of the material during the process. Default values in the form of gradients for humidity and temperature are provided, with the temperature constantly increasing and the relative humidity constantly decreasing. In addition, a rhythm in the ventilation of the material to be dried is provided. The

&iacgr;&ogr; Form pieces are only blown on for a while and then rest for a while in still air. The aim of this is to even out the drying process and to avoid stress cracks, at least in the shrinkage phase. The form pieces are arranged in several rows one behind the other in the direction of blowing, with only the front form pieces being blown on from the front. The other rear form pieces are essentially only blown over tangentially by the drying air, so that this also results in a different drying progress over the depth of the covering. Ultimately, the drying process takes a certain amount of time.

The object of the present invention is to show a possibility for better and yet safer drying.

The invention solves this problem with the features in the main claim.

The invention provides for blowing air onto the moldings from at least two different directions and using two or more perforated plates. Unlike in the prior art, the perforated plates have the purpose of creating a certain diffuser effect in order to even out the drying. Accordingly, the moldings can also be made solid.

The perforated sheets make it possible to blow directly onto the moldings on different sides and thus accelerate the drying process. It is advisable to use a

(Continued on page 3 of the original description)

Oscillating conditioning of the drying air is recommended, although this is not absolutely necessary. Oscillating conditioning does, however, have the advantage of faster and more economical drying.

The perforated sheets can be arranged at a distance from the molds, which improves the diffuser effect ^. On the other hand, the molds can also take on a shaping support function and be designed as a support frame and/or mold carrier. This allows even complexly shaped and unstable molds to be dried safely and quickly. Using suitable covers, particularly sensitive areas of the molds can also be sealed off from the direct flow of drying air. This allows the drying progress to be influenced locally.

^: ,:! For the design of the perforated sheets or support frames and/or

■ ;&idiagr; Various advantageous embodiments are specified in the subclaims for the mold carrier.

The device according to the invention can be used for any dry material, e.g. wood or the like. It is particularly suitable for ceramic moldings, with particular advantages for thin, solid moldings, such as roof tiles, tiles, etc.

The invention is illustrated by way of example and schematically in the drawings. In detail:

Figure 1 : a diagram with the gradients of

Temperature and relative humidity,

Figure 2 : a schematic representation of a dryer,

&Igr;&Idigr;

Figure 3 : an enlarged view of the

Mouldings with perforated sheets in the air stream,

Figure 4 : a variant of Figure 3 for roof tiles

and

Figures 5 to 7: Individual designs of perforated sheets.

Figure 2 shows a schematic representation of a

Dryer (1) for ceramic moldings (4). The example shown is a chamber dryer with only one zone or chamber (2).

Alternatively, it can also be a tunnel dryer with several zones that are preferably sealed off from each other. The ceramic moldings (4) are placed on a frame

(3) which is rigid or movable, in particular

• can be mobile. In the embodiment shown, '; &lgr; the dry goods are arranged in only one layer. In a corresponding modification, several layers can also be arranged

■ be arranged one above the other in tiers at a suitable distance from one another.

The moldings (4) are preferably dried in an air flow (5) conditioned according to relative humidity and/or temperature. The air flow (5) is moved by a blowing device (21), which is, for example, one or more fans with corresponding air ducts. The dry air can be sucked in from the room or supplied from outside or even mixed from outside and room air.

In the preferred embodiment, the moldings (4) are relatively thin-walled, solid structures, e.g. roof tiles, tiles or the like. The moldings

(4) are preferably blown directly with the air flow (5), whereby the air flow (5) is directed transversely or obliquely to

one or both broad sides of the moldings (4). Accordingly, the moldings (4) are preferably only in one layer and are blown from above and below.

In a modification of the embodiment shown in Figure 2, it is possible to provide several blowing devices in conjunction with a multi-layer frame (3), so that each level or layer is blown separately. It is also possible to arrange two moldings (4) one above the other with relatively little or no spacing and to first dry their outer sides, then turn them over and then dry the inner sides that are now on the outside.

In the preferred embodiment of the invention

the moldings (4) are blown with the air stream (5) during the entire drying process. The previously usual rest phases and the blowing rhythm are no longer required. They are replaced by an oscillating conditioning of the drying air, which is described in more detail below. Alternatively, it is possible to temporarily suspend the blowing and, if necessary, to develop a certain rhythm.

The moldings (4) are surrounded on at least two sides by perforated plates (6, 7), which are preferably arranged in front of the moldings (4) in the blowing direction. In the preferred embodiment of Figures 3 to 7, perforated plates (6, 7) are arranged at the top and bottom when the moldings (4) are blown on both sides.

The perforated plates (6,7) are characterized by a large number of relatively small openings, between which at least in some areas there may be larger openings (13). The openings may also have a different shape, for example the smaller ones are circular and the larger ones are rectangular. The number,

The size, shape and arrangement of the openings (13) can influence the air flow (5) and its effect on the molding (4).

In addition, the perforated plates (6,7) can have covers (14) through which sensitive areas of the moldings (4) can be sealed off from the air flow (5) ·.·,.

The perforated plates (6,7) act as a type of diffuser. They can also be designed differently to fulfill this function. In the embodiment shown in Figure 3, the upper and lower perforated plates (6,7) are connected to one another by vertical side walls to form a housing (11) in which the moldings (4) are arranged.

The perforated plates (6,7) can be arranged at a distance from the formations (4), which is preferably the case with the upper perforated plates (6). This increases the diffuser effect. At least the lower perforated plates (7) can also be arranged close to the formations (4) and possibly be in contact.

The moldings (4) rest on suitable supports, preferably a support frame (8), which can also have one or more supports (10) to adapt to the molding design. These are preferably strips. The support frame (8) can also have larger cutouts (9) in one or more places, which allow the air flow (5) to pass through over a larger area.

In the embodiment of Figure 3, the support frames (8) are arranged separately and above the lower perforated plates (7). In the embodiment of Figure 4, the support frames (8) themselves are designed as perforated plates (7) and have suitable wall perforations for this purpose.

The cutouts (9) can preferably be covered on the underside with a suitable perforated cover (24) which acts as a diffuser. As Figure 4 shows, movable control flaps (23) can also be arranged on the cutouts (9) which throttle the air flow (5).

Figure 5 shows a variant of the lower perforated plate (7), which is designed here as a mold carrier (12). Such a

The omega-shaped design is particularly suitable for ridge tiles. The curvature of the mold carrier (12) is adapted to the arch shape of the brick and supports it. The holes or openings (13) are preferably located in the curvature area of the mold carrier (12) and ensure targeted drying of the relatively sensitive brick arch. The side flanges of the omega-shaped mold carrier that adjoin the curvature edge can be solid or also perforated and support the brick edges.

The mold carrier (12) can be an integral part of a support frame (8). However, it can also be designed as an exchangeable insert for such a support frame. Modifications to the mold carrier design shown are possible in any way and in adaptation to the respective molding shape.

Figures 6 and 7 show an enlarged view of the lower and upper perforated plates (6,7) with the arrangement of the holes or openings (13) and the covers (14). Here too, it is possible to design the perforated plates (6,7) as smaller and replaceable units that are hung in a corresponding supporting structure or in a supporting frame (8) or fastened in another suitable manner.

Figure 4 shows a further modification. The perforated plates (6, 7) or the support frame (8) are designed here as air guide elements with built-in or connected guide channels (22) for the air flow. The blowing device can be connected to the front sides of the perforated plates or support frame. In the area of the moldings, the air flow is then diverted towards the molding. This reduces the construction effort of the blowing device and allows

&iacgr;&ogr; a denser loading of the frame (3).

The conditioning of the dry air mentioned at the beginning is carried out by means of a suitable air conditioning device (18). This can be designed in different ways. In the preferred embodiment, it contains at least one humidification device (20) with which steam or water can be introduced into the dry air. In addition or alternatively, the air conditioning device (18) can also have a heater (19) for the circulating air and/or the outside air or fresh air.

The air conditioning device (18) has a suitable control (15) with which the conditioning of the dry air can be changed in an oscillating manner. The control (15) is preferably freely programmable. It is designed as an electronic circuit or as a computer with one or more microprocessors and has suitable data storage, bus systems, input and output units and interfaces for connecting to other control units, e.g. a dryer-wide machine control. The control (15) can also be integrated into a higher-level control or assigned in a modular manner.

The control system (15) stores default values for temperature and relative humidity, which are adapted to the drying behavior of the respective moldings (4). They are

preferably in the form of gradients (17). For example, for the temperature there is a heating phase with increasing temperatures, a holding phase with a constant temperature and a final phase with a rising temperature again. As the drying progresses in the molds (4), the sensitivity to stress and cracking decreases, so that at the end the temperature can rise relatively quickly and to high values. The relative humidity shows the opposite behavior. It is relatively high at the beginning so that the molding (4) does not dry out too quickly and decreases quickly at the end of the holding phase of the temperature. Temperature and relative humidity relate to the drying air flow (5) and are dependent on each other.

As Figure 1 shows, during the drying process the humidity and/or the temperature fluctuate around or at the set value or gradient (17). Practical values for the fluctuation range are

e.g. for humidity approx. ± 10% and for temperature approx. ± 3°C. These example values can vary up and/or down depending on the material being dried. The oscillating fluctuation means that the values for temperature and/or relative humidity briefly exceed the set value, then briefly fall below it, then exceed it again, etc. The fluctuation preferably takes place around the set value, which forms the O-line. However, it can also happen that the fluctuations are shifted compared to the set value and take place above or below it.

The fluctuations can have a certain rhythm. This is the case, for example, if the value changes are specified by the control (15) as programmed values. The rhythm can be set using a timer (16).

• · * I«

However, control can also take place, whereby the actual values of temperature and/or humidity in the air flow (5) or on or in the molding (4) are measured using suitable sensors. In the control system, limit values for the fluctuation amplitude are then specified/when these are reached, the control system (15) switches over and controls the air conditioning system (18) in the opposite direction.

In the control (15) or the regulation, both values δ for humidity and/or temperature can be influenced and monitored individually. In a simplified embodiment, it is also possible to control only one parameter, e.g. humidity. The other parameter then changes accordingly. As part of the regulation, one or both parameters can be monitored as actual values.

In the example shown, the oscillating change in air conditioning takes place during the entire drying process. Alternatively ^, this can also take place in stages, e.g. only during the heating and holding phases of the temperature. Other forms of stage formation are also possible.

Modifications of the invention shown are possible in various ways. For example, the air flow (5) does not have to be in the

The design and arrangement of the perforated plates (6, 7) is also variable. The features of the described embodiments can be exchanged or combined as desired. The moldings can also be blown from more than two sides, whereby the arrangement and shape of the perforated plates adapts accordingly. In addition, the moldings (4) can have a different shape and can also be made of materials other than ceramic.

REFERENCE SYMBOL LIST

1 dryer 2 Zone 3 frame 4 Moulding/ Brick 5 Airflow 6 Perforated sheet, diffuser, top 7 Perforated sheet, diffuser/ bottom 8th Support frame 9 Excerpt 10 support, strip 11 Housing 12 Mold carrier, curvature 13 opening 14 cover 15 steering 16 Time element 17 gradient 18 Air conditioning · 19 • Heating 20 Humidification device 21 Blowing device 22 channel 23 Control flap 24 cover

Claims (13)

•—•12·*—· · · ANl DE-G 295 06 470.6 Note: Novokeram ... File: 220-64 of 04.07.1996 5 NEW PROTECTION CLAIMS 1.) Device for drying moldings, in particular roof tiles, in an air stream, whereby the moldings are arranged on an air-permeable base and the "dryer has a blowing device for generating an air stream from at least two different directions, characterized in that the blowing device (21) directs the air stream (5) directly onto the moldings (4) arranged in one or two layers in the blowing direction, whereby perforated plates (6, 7) are arranged in front of the blown sides of the moldings (4) and the moldings (4) are arranged lying on a perforated plate (7) which is designed as a support frame (8) adapted to the shape of the molding or as a mold carrier (12). 2.) Device according to claim 1, characterized in that the other perforated plate(s) (6) are arranged at a distance from the molding (4). 3.) Device according to claim 1 or 2, characterized in that the support frame (8) has a perforated wall and a cutout (9). 4.) Device according to claim 3, characterized in that an adjusting flap (23) and/or a perforated cover (24) is arranged on the cutout (9). 5.) Device according to claim 4, characterized in that the control flap (23) and/or the perforated cover (24) are arranged at a distance in front of the molding (4). 6.) Device according to claim 1 or one of the following, characterized in that the support frame (8) has channels (22) for the supply and &iacgr;&ogr; removal of air. ■ ■ 7.) Device according to claim 1 or one of the following, characterized in that the perforated plates (6, 7) have openings (13) of different sizes. 8.) Device according to claim 1 or one of the following, characterized in that the perforated plates (6, 7) have one or more covers (14) for the molding (4) in some areas. 9.) Device according to claim 1 or one of the following, characterized in that the blowing device (21) directs the air flow (5) onto at least one broad side of the solid moldings (4) and transversely or obliquely to their surface. 10.) Device according to claim 1 or one of the following, characterized in that the perforated plates (6, 7) are arranged in front of the molding (4) in the blowing direction and are aligned transversely to the air flow (5). 11.) Device according to claim 1 or one of the following, characterized in that the dryer (1) has a control (15) and a Air conditioning device (18) for at least step-by-step oscillating changes in temperature and/or humidity, 12.) Device according to claim 11, characterized in that the control (15) has a timing element (16). 13.) Device according to claim 11 or 12, characterized in that the air conditioning device (18) has a humidification device (20).