DE3737254A1 - COOLING CHAMBER FOR CONVECTION COOLING OF SURFACE GOODS - Google Patents

Abstract

A convection cooling vessel for materials exhibiting surfaces in arrangements with interspaces which can be flowed through, in particular of block charges made of light metal semifinished products, has a fan which delivers into an exhaust duct and on the suction side of which a forked pipe is arranged; on each leg of the forked pipe, there is a shut-off and control valve. Provided symmetrically in relation to the material are inflow ducts which are assigned to the legs of the forked pipe. Each inflow duct has a further shut-off and control valve. The shut-off and control valves in the forked pipe and in the inflow ducts can be adjusted in such a manner that, because of the suction effect of the fan, the material can be flowed through in the main flow or in the part flow and the flow direction of the cooling medium can be reversed. <IMAGE>

Description

The invention relates to a cooling chamber for the conventional cooling of flat goods in arrangements with flowable gaps, in particular re of so-called block batches of light metal semi-finished products, the upper Concept of claim 1 specified genus.

In the heat treatment of good stacks, e.g. B. light metal block batches, after the homogenization annealing must be a highly effective, if possible the same moderate cooling of the goods. This cooling must, in Ab dependence on the metallurgical specifications, controlled or by holding phases in which the temperature must not change, interrupted will.

Such areal goods can be several, for example a stack of superimposed layers of light metal bolts, the one with an initial material temperature of 580 ° C the cooling process be subjected. The mass of such a batch can be 25 t and more be. In the first hours of the cooling process, 8,000,000 up to 10,000,000 KJ (8-10 GJ) of thermal energy can be dissipated.  

These numbers illustrate the cooling of such a batch related problems, especially considering the point of view, that the temperatures of the individual bolts of such a batch, the one Variety of bolts may contain just around during the cooling process may differ from each other by a few degrees C.

To solve this cooling problem, it is common to put the batch to be cooled in a chamber, the so-called "cooling chamber", in which to help air circulation is generated by fans. With such cooling There are two basic types of chambers, namely cooling chambers, which are used in open circuit work, as well as cooling chambers that follow the principle of ge use closed circuit.

In the cooling chambers with an open circuit, ambient air is applied to the Batch inflated and then withdrawn from the cooling chamber, while in cooling chambers with a closed circuit, those from the fan The extracted air from the cooling chamber is usually water cooled cooler serving as a heat exchanger and then the goods to be cooled flows through.

To ensure sufficient uniformity of cooling in these cooling processes and thus a homogeneous temperature distribution in the cooling chamber enough, one uses the so-called "reversing", ie a reversal of the Direction of flow of the blowing air. This reversal is almost over finally by reversing the direction of rotation as the flow drive used axial fan causes. This solution, which is simple in terms of effort has one major disadvantage, however: one for reversing the flow A suitable fan must have neither a leading nor a trailing wheel and must also have blades that are set at 45 ° so that the Flow performance in the two directions at least approximately the same is. This limitation in the design of the axial fan however the possibility of an increase in pressure for the blowing medium and thus an improvement in efficiency is severely limited, so that at Batches with high flow resistances, such as those for flat goods in arrangements with flowable gaps  are given, not those to achieve the high cooling rates required large volume flows can be achieved. This is especially true then when a cooling unit is additionally switched on with a closed circuit must be poured.

Another solution known from DE-OS 30 49 162 is the Be blow air to the batch by means of a fan and through an adjustment flap to change the direction of the air flow. Such However, the device is only suitable for simple dryers to which none particularly high requirements in terms of uniform cooling over a large volume of goods is provided; with the high demands on a uniform temperature distribution as used for cooling Light metal batches are required, this device does not lead to desired result.

Corresponding disadvantages also apply to that from DE-OS 26 00 724 known air circulation device.

A cooling chamber for convection cooling of flat goods in An orders with flowable spaces between the specified genus finally from DE-OS 32 15 509. A fan presses the Gas flow through the gaps in the flat material; to the desired, even temperature distribution over the entire volume of the To get good, the direction of the gas flow through cover plates like slide plates can be controlled. The basic disadvantage of this Device is that the flow through the gaps in the good only on the pressure side of the fan, i.e. the batch of which Cooling air is blown. By blowing on with Help from rays that pass through the gaps in the area occur, there are locally very different cooling speeds, those with the high demands on uniform temperature distribution when cooling high-quality light metal batches after homogenization are not compatible.  

The invention is therefore based on the object of a cooling chamber Convection cooling of flat material in arrangements with flowable Spaces, especially of so-called block batches made of light metal Semi-finished products to create the specified genus, in which the above mentioned Disadvantages do not occur.

In particular, a device is to be proposed that also has a very even temperature distribution over the entire material to be cooled ensures that extremely large bulk goods have to be treated.

This is according to the invention by the characterizing part of claim 1 specified characteristics achieved.

Advantageous embodiments are characterized by the features of the subclaims Are defined.

The advantages achieved with the invention are based on the fact that the intermediate clear the area of a well-defined sub-stream of the flows through the air flow sucked in by the fan and thereby ge be cooled, so that the cooling can be precisely defined. Nevertheless the entire flow is available on the fan, which means that the operating temperature by mixing the blowing air with fresh air of the fan can be kept within limits. This in turn enables the Use of industrial fans with common storage and drive technology nik without special designs of high temperature fans must be used.

Due to the arrangement of the goods on the suction side of the fan, a uniform flow through the gaps in the good achieved; the The flow direction can be changed as desired using the flaps. This compares with facilities where this involves the rotation Direction of the fan must be changed, a big advantage, because when the direction of rotation of the fan changes, this is indicated drive, braked and must be started again, which is the permanent  drove to considerable design and wear problems. In the end can with the device according to the invention the gaps in the good can also be flowed through in a closed circuit, which is particularly true proves to be extremely advantageous during holding phases.

For special requirements, namely if, for example, with one Cooling chamber hold times can be realized at certain temperatures additional flaps can be installed in the side walls will.

The temperature changes when the cooling chamber is insulated accordingly temperature of the goods in the holding phase hardly, so that in almost all Cases of the additional installation of a heater are unnecessary.

The invention is described below using an exemplary embodiment under Be access to the accompanying schematic drawings explained in more detail. Show it

Fig. 1 shows a cross section through a cooling chamber, and

Fig. 2, the cooling chamber of FIG. 1 partly in longitudinal section and partly in side view.

The cooling chamber shown in the figures, generally indicated by the reference numeral 10 , receives a block batch 12 which, as shown in FIG. 1, consists of a stack of several layers of light metal bolts. The block batch 12 rests on a conventional base 14 , the height of which can be adjusted by a schematically indicated adjusting device.

Between the individual light metal bolts of the block batch 12 inevitably gaps, which are flowed through in a manner to be explained by a cooling medium, generally air.

The block batch 12 is surrounded by a heat-insulated housing 16 with side walls 16 a and a false ceiling 16 b , which has such a distance from the side surfaces of the block batch 12 that between the side walls 16 a of the housing 16 and the block -Charge 12 channels 13 a , 13 b arise for the supply and discharge of the blowing air.

Perpendicular and promotes symmetrical about the block-charge 12, that is above the intermediate ceiling 16 b a powerful axial fan 18 is disposed with guide vanes, which are arranged in a perpendicular to the axial fan 18 Ausblasekanal 20th This blow-out channel 20 can be completely or partially closed by a shut-off and regulating flap 22 designed as a louver flap.

From the blow-out duct 20 , as seen in the flow direction, branch off behind the axial fan 18 , but in front of the shut-off and regulating flap 22 on each side, at least one connecting duct 24 a , 24 b , each with a shutter flap 26 a , 26 b serving as a shut-off and regulating flap is provided. These connecting channels 24 a , 24 b each open into an inflow channel 28 a , 28 b arranged laterally from the block charge 12 . Upstream from the mouths of the intermediate channels 24 a , 24 b , shutter flaps 30 a , 30 b serving as shut-off and regulating flaps are also built into the inflow channels 28 a , 28 b . Through these inflow channels 28 a , 28 b , which are aligned with the channels 13 a , 13 b , ambient air can be drawn in by the axial fan 18 and sucked in by the block charge 12 .

To the block charge 12 , downwards, the axial fan 18 is connected to a downpipe 32 with a left leg 32 a , a right leg 32 b and a collecting pipe 32 c . In each leg 32 a , 32 b there is a shut-off and regulating flap 34 a , 34 b . The legs 32 a , 22 b face the channels 13 a , 28 a and 13 b , 28 b , while the collecting tube 32 c is connected to the axial fan 18 .

Finally, swivel flaps 36 a , 36 b are provided, which are located approximately at the level of the false ceiling 16 b and the channels 13 a , 13 b on the two sides of the block batch 12 between their side walls and the side walls 16 a of the housing 16 open or close.

These swing flaps 36 a , 36 b are formed by sections of the insulated side walls 16 a .

In this cooling chamber 10 , the cooling medium air is sucked by the axial fan 18 through the gaps in the block charge 12 , the corresponding flow direction being predetermined by setting the respective louvre flaps. Since the shape of the flow cross-sections tapering towards the block charge 12 is continuously reduced, jet-like impacts and thus uneven cooling are avoided.

Should z. B., as shown in Fig. 1, the flow from right to left through the block charge 12 , the blind flap 34 a located in the right leg 32 a of the downpipe 32 is closed and the blind flap located in the left leg 32 a 34 b open. At the same time, the louver flap 30 a in the inflow channel 28 a must be opened and the louver flap 30 in the inflow channel 28 b must be closed.

Of course, the two flaps 36 a , 36 b are open.

The air sucked in by the axial fan 18 now flows through the inflow channel 28 a in the direction of the arrows on the right side of the block batch 12 through the channel 13 a downwards, through the spaces in the block batch 12 , on the left side of the Block batch 12 through the channel 13 b upwards and then through the left leg 32 b of the downpipe 32 and the collecting tube 32 c to the axial fan 18 , which conveys the air into the blow-out channel 20 .

Due to the warming of the air as it passes through the area there is an uneven temperature distribution in the horizontal Direction of the flat material, so that the direction of flow in rule moderate intervals must be reversed.

For this purpose - with the exception of the flaps 36 a , 36 b - the previously opened flaps are closed and the previously closed flaps are opened, so that the air is now sucked in via the inflow channel 28 b and from the left side through the channel 13 b flows into the spaces in the large panels of material 12 exits on the right side of the laminar material 12 and then through the channel 13 a and right leg 32 a arrives at the axial fan 18 which conveys the heated air into the Ausblasekanal 20th

By partially opening or closing the flaps 34 a , 34 b in the two legs 32 a , 32 b of the downpipe, it can be achieved that the block batch 12 is flowed through by a precisely defined partial flow of the air flow sucked in by the axial fan 18 . This allows the cooling effect to be metered precisely.

In addition, by partially opening the flaps 26 a and 26 b in the connecting channels 24 a , 24 b, the extracted air flow can be mixed with fresh air in order to achieve certain temperature effects. In addition, the operating temperature of the fan 18 can be kept within limits.

For special requirements when e.g. As with the cool-down chamber 10 holding times are to be realized at a certain temperature, the flaps 36 a, 36 b in channels 13 a, b 13 pivoted and thereby the Ge housing 16 verschlosen. With appropriate insulation, the temperature of the block charge 12 hardly changes during such a holding phase, so that the additional installation of a heater is unnecessary in almost all cases.

Finally, by closing the flaps 30 a , 30 b in the inflow channels 28 a , 28 b and opening the flaps 26 a , 26 b in the intermediate channels 24 a , 24 b, the cooling chamber 10 can also be operated in a closed circuit. This is particularly useful when the block batch 12 must be kept at a certain temperature in the holding phases.

The inlet cross sections of the two legs 32 a , 32 b of the downpipe 32 and the cross sections of the inflow channels 28 a , 28 b and the channels 13 a , 13 b have a rectangular shape; the long rectangular axis corresponds to the zone length for which a fan is intended; the forging of rectangular cross-section to the circular intake cross-section of the axial fan 18 follows it in the collecting pipe 32 c of the bifurcated pipe 32nd

The channels 13 a , 13 b on the two sides of the block batch 12 are provided with flow control devices.

Furthermore, 20 soundproofing devices can be provided in the blow-out duct.

In the illustrated and described embodiment, the fan 18 is designed as an axial fan; however, a radial fan can also be used in the same way.

Claims (15)

1. cooling chamber for convection cooling of flat material in arrangements with flowable gaps, in particular block batches of light metal semi-finished products,

• a) with at least one fan conveying into a blow-out duct, characterized by the following features:
• b) on the suction side of the fan ( 18 ) is a downpipe ( 32 ) is arranged;
• c) in each leg ( 32 a , 32 b ) of the downpipe ( 32 ) a shut-off and regulating flap ( 34 a , 34 b ) is provided;
• d) symmetrical to the material ( 12 ) are inflow channels ( 13 a , 28 a , 13 b , 28 b ) which are assigned to the legs ( 32 a , 32 b );
• e) each inflow channel ( 13 a , 28 a , 13 b , 28 b ) has a further shut-off and regulating flap ( 30 a , 30 b );
• f) the shut-off and regulating flaps ( 34 a , 34 b ; 30 a , 30 b ) in the downpipe ( 32 ) and in the inflow channels ( 13 a , 28 a , 13 b , 28 b ) are adjusted so that due to the suction effect of the fan ( 18 ) flows through the material ( 12 ) in the main or partial flow and the flow direction is reversed.

2. Cooling chamber according to claim 1, characterized in that a tread cross sections of the legs ( 32 a , 32 b ) of the downpipe ( 32 ) and the cross sections of the inflow channels ( 28 b , 28 b ) have a rectangular shape. 3. Cooling chamber according to claim 2, characterized in that the long rectangular axis of the rectangles corresponds to the zone length for which a fan ( 18 ) is provided, and that the deformation of the rectangular cross-section on the circular suction cross-section of the fan ( 18 ) in the manifold ( 32 c ) of the downpipe ( 32 ). 4. Cooling chamber according to one of claims 1 to 3, characterized in that a shut-off and regulating flap ( 22 ) is arranged in the blow-out channel. 5. Cooling chamber according to claim 4, characterized in that seen in the direction of flow in front of the shut-off and regulating flap ( 22 ) in the blow-out channel ( 20 ), a connecting channel ( 24 a , 24 b ) is provided, which the blow-out channel ( 20 ) with the arranged on both sides of the goods ( 12 ) th inflow channels ( 13 a , 28 a , 13 b , 28 b ). 6. cooling chamber according to claim 5, characterized in that each Ver connection channel ( 24 a , 25 b ) with a shut-off and regulating flap ( 26 a , 26 b ) is provided. 7. cooling chamber according to one of claims 5 or 6, characterized in that each connecting channel ( 24 a , 24 b ) between the regulating flaps ( 30 a , 30 b ) and the connection to the downpipe ( 32 ) in the inflow channel ( 13 a , 28 a , 13 b , 28 b ) opens. 8. cooling chamber according to one of claims 1 to 7, characterized in that the shut-off and regulating flaps at least partially as a shutter pen are executed. 9. Cooling chamber according to one of claims 1 to 8, characterized in that the inflow channels ( 13 a , 28 a , 13 b , 28 b ) on both sides of the material ( 12 ) have flow control devices. 10. Cooling chamber according to one of claims 1 to 9, characterized in that an axial fan is used as the fan ( 18 ). 11. Cooling chamber according to one of claims 1 to 9, characterized in that a radial fan is used as the fan ( 18 ). 12. Cooling chamber according to one of claims 1 to 11, characterized in that a good ( 12 ) surrounding the housing ( 16 ) is provided with heat and sound insulation. 13. Cooling chamber according to one of claims 1 to 12, characterized in that a good ( 12 ) surrounding the housing ( 16 ) by pivotable flaps ( 36 a , 36 b ) can be shut off. 14. Cooling chamber according to claim 13, characterized in that the flaps ( 36 a , 36 b ) are formed by sections of the insulated side walls ( 16 a ) of the housing ( 16 ) and at the level of a false ceiling ( 16 b ) Housing ( 16 ) are. 15. Cooling chamber according to one of claims 1 to 14, characterized in that noise protection devices are provided in the exhaust pipe ( 20 ).