CH676808A5 - - Google Patents

Description

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CH 676 808 A5

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description

The invention relates to a device for extracting pollutant-laden air from the surface area of immersion baths for the surface treatment of workpieces, in particular their galvanizing, a suction wall with an internal suction channel being carried along both sides of the immersion baths and the walls having inlet openings for the air to be extracted.

A suction device with the aforementioned features is in the publication DE-Z. «Haustechnik - Bauphysik - Umwelttechnik» gi, issue 11/1979, page S 10/340 to S 14/344; In the suction device shown there, an edge suction on both sides is proposed in that a suction wall is arranged on both longitudinal sides of the immersion trough, via which the rising polluted air is sucked off. This is associated with the disadvantage that considerable amounts of air have to be extracted and led away via the suction walls on both sides in order to redirect the thermally induced air buoyancy from the bath surface into the suction channels; consequently, the efficiency of such devices is insufficient.

In the same publication, a suction concept is also described, in which blow openings are arranged on one long side of the immersion tub and a suction hood is arranged on the opposite long side, so that a blowing jet running parallel to the bath surface and supposedly shielding the bath upwards is generated and captured by the suction hood and is led away. This has the disadvantage that, due to the straight flow, considerable flow velocities have to be generated in order to shield the bath surface and redirect the thermally induced buoyancy in polluted air; however, a satisfactory suction effect cannot be achieved with such a suction device either.

The invention is therefore based on the object of improving a suction device with the generic features in such a way that the rising air contaminated with pollutants can be captured as completely as possible and can be supplied for cleaning via the suction walls, while at the same time the effort required for the suction is within a reasonable range should hold.

To solve this problem it is provided according to the independent patent claim that on each suction wall there is a blow pipe running the length of the immersion tub with blowing nozzles directed over the bath surface. Advantageous refinements and developments are specified in the dependent claims.

The invention is associated with the advantage that the reverse flow of atmospheric air, which opposes the air column caused by the thermal pollution and introduces the polluted air into the suction channels arranged on the side, can be kept low by the air that is blown in laterally via the injection openings towards one in the direction of the Extraction channels directed air vortex, which favors the deflection of the air column.

This advantage according to the invention is reinforced by the fact that sharp-edged baffles are arranged on the injection nozzles in the outflow direction of the air reduced above the metal bath, which also reduces the proportion of sealing air that is still to be led through this hydraulically effective outlet cross section.

It has a particularly advantageous effect in the invention that corresponding suction walls with blowpipes are carried on both sides of the immersion tub, because in this way the blowing air flows and baffles directed towards one another complement each other in the sense of narrowing the hydraulically effective outlet gap between the suction walls, so that the proportion of can be kept low by this exit gap sealing air to be led.

According to an advantageous embodiment of the invention, the injection nozzles are aligned with baffles parallel to the bath surface; According to the invention, however, it may also be expedient to arrange the injection nozzles with the guide plates at an upward angle to the bath surface; This is associated with the advantage that the height of the laterally arranged suction walls can be reduced in order to lower the overall height of the zinc bath. A parallel alignment of the injection nozzles realized at a low overall height could lead to the deflection vortex not being able to develop sufficiently in polluted air due to the lower free height, so that disturbances in the suction would have to be expected. To remedy this possible disadvantage, an upward arrangement of the injection nozzles at an angle to the bath surface is therefore proposed, according to which a roof-like shielding results over the bath surface.

According to the invention, a further possibility of adapting the structural conditions in the case of a submersible bath with suction walls is to adjust the height of the blowpipes arranged above the side suction walls, in order in this way to summarize the advantages of a low overall height of the immersion bath and a suction system according to the invention.

In general, in the implementation of the invention, a ratio of the proportion of air to be blown through the injection nozzles and the sealing air of one tenth to nine tenths, based in each case on the total volume of extracted air, has been found to be the optimal upper limit for the measurement of the amount of blown air.

With a view to an advantageous practical approach5

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application of the invention, the baffles should not reach closer than to the vertically projected edge of the immersion pan in order to ensure free access to the immersion pan over its entire width; on the other hand, the baffles should have this position with regard to the smallest possible hydraulic outlet cross-section for the polluted air.

So far as the suction walls have an upwardly recessed, funnel-shaped design, it has been shown to be advantageous to arrange the injection nozzles on arms connected to the blowpipe, which compensate for the distance of the blowpipe caused by the recess from the edge of the immersion bath and the injection nozzles back into the bring optimal position. In order to improve access to the immersion pan here, it is advantageous according to a preferred embodiment of the invention to arrange the arms so as to be pivotable about the longitudinal axis of the suction wall, so that the entire free opening space along the recessed suction walls is available for access to the immersion pan.

It is also advantageous to design the injection nozzles as a slot running over the entire length of the blowpipe on a pivotable flap and to arrange a single guide plate with a continuous tear-off edge in front of it.

In the drawing, exemplary embodiments of the invention are shown, which are described below. Show it:

1 is a suction device in a schematic sectional view,

2 is a graphical representation of a suction wall with blowing device,

. 3 shows the device according to FIG. 1 with a schematically indicated air duct,

4 shows another embodiment of the suction device in a view according to FIG. 1.

1 shows an exemplary embodiment of the invention with two suction walls 11 arranged on the longitudinal sides of an immersion pan 10. The suction walls 11 jump back with their side facing the immersion pan 10 diagonally upwards from the upper edge of the immersion pan, so that there is an intermediate space at the upper end of the two suction walls 11 which exceeds the width of the immersion pan 10. The suction walls 11 each have a suction channel 12 in their interior and also inlet openings 13 for the polluted air to be extracted.

A blow tube 16 is arranged on supports 15 on a top bar 14 running on the suction wall 11; Arms 17 are attached to the blowpipe 16 and are connected to the blowpipe 16 for an air flow to be carried out. In the position shown in FIG. 1, the arms 17 are aligned from the suction wall 11 to the immersion trough 10 and parallel to the surface 18 of a metal bath, in particular a zinc bath, located in the immersion trough 10. At the front end of the arms 17 there are injection nozzles 19 as well as an underlying baffle plate 20, which is arranged in a continuation of the direction of the associated arm 17 and is formed with sharp edges on its front edge. With its front edge, the respective guide plate 20 extends to the edge of the immersion tank 10 projected vertically upwards. With a view to sealing the sides of the suction chamber 24 formed above the immersion pan 10 by the suction walls 11 with a blower device 16, 17 also in the area of the carrier 15, sealing sheets 21 are provided under the blowing arms 17, which are also shown in a manner not shown for the Sealing of the end faces of the immersion tub 10 are set up.

In order to be able to use the entire free space between the suction walls 11 above the immersion pan 10 for the operations, the arms 17 are pivoted through an angle of two hundred and seventy degrees around the longitudinal axis of the associated suction wall 11, so that they move out of the operating position into an additionally shown rest position can be transferred; For this purpose, the blowpipe 16 with arms 17 attached to it can expediently be pivoted about the longitudinal axis of the suction wall.

As can be seen in more detail in FIG. 2, a compressor 22 for the blowing air to be introduced into the blowing pipe 16 and, on the other hand, a geared motor 23, by means of which the blowing pipe 16 can be pivoted with arms 17, are arranged on the one hand at the ends of the blow pipe 16 carried over the elongated immersion tub 10 can. In addition, the injection nozzles are arranged on a continuous flap 17 in the form of a slot, so that the entire length of the immersion tub 10 can be coated with blowing air.

The device shown has the following effect during operation of the immersion tank: from the suction space 24 formed between the suction walls 11, the pollutant-laden air, which rises from the surface of a metal bath, for example, which is hot by four hundred and fifty degrees Celsius, is sucked into the suction wall 11 via the inlet openings 13 and by fed here from a downstream cleaning device, not shown in detail. In the arrangement of two suction walls shown here, the required volume flow to be extracted per unit of time is drawn in half over the two suction walls 11.

The volume flow to be extracted is made up of the respectively supplied volume flows of blown air, which is introduced into the suction chamber 24 via the arms 17, and sealing air, which is drawn into the suction chamber 24 via the hydraulically effective gap 25, and the rising thermals above the bath surface 18 is opposite. The hydraulically active gap 25 is further narrowed apart from the component-related geometric limitation by the action of the sharp-edged guide plate ends 20, which lead to a contraction of the thermal column, and by the blowing air guided over the guide plates 20, which together with the sealing air hydraulically closes the gap 25 .

In Fig. 3 is a schematic line

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the resulting air flow indicated; Due to the suction effect emanating from the suction walls 11, the blown air blown in parallel to the bath surface 18 via the guide plates 20 is deflected into the suction space 24 and induces a circular vortex 26 there, via which the air to be suctioned is led to the inlet openings 13 in the suction walls 11 on both sides. There is only a limited free space between the parts of the thermopile above the bath 10, which has to be sealed off, and the sealing air of the thermopile that is still required flows into this free space under the suction effect of the suction walls 11 in the opposite direction into the suction chamber 24 and is also deflected there in a vortex-like manner to the laterally arranged inlet openings 13 of the suction walls 11.

From Fig. 3 it follows that due to the narrowing of the free car cross-section to be sealed off by means of the sealing air between the suction space 24 and the ambient atmosphere, the need for sealing air is substantially reduced, the total amount of air to be extracted from the suction space 24 being significantly reduced at the same time; at the same time, the efficiency of the isolation of the suction chamber 24 from the ambient atmosphere is significantly improved. It has been found here that a proportion of blown air of up to ten percent of the volume flow to be extracted is sufficient to achieve the advantages according to the invention, with which the energy expenditure for the blown air supply can be kept low. However, it goes without saying that the volume flow of blowing air to be blown in on the one hand and the volume flow of sealing air dependent on it on the other hand depend on the structural conditions of the immersion bath arrangement 10 with suction walls 11 and must therefore be optimized for each installation.

FIG. 4 shows an exemplary embodiment in which the arms 17 with injection nozzles 19 are arranged at an angle to the bath surface 18, so that a roof-like shielding of the suction space 24 results, as is indicated by the dash-dotted line 27.

As indicated in FIG. 4 by the arrows 28, the blowpipes 16 can be height-adjustable with a view to an optimal design of the suction space 24 depending on the height of the side walls 11, this height adjustment being particularly advantageous if the surface 18 is parallel to the bath surface 18 Arms 17 with blowing nozzles 19 affects.

The features of the subject matter of these documents disclosed in the above description, the patent claims, the abstract and the drawing can be essential individually or in any combination with one another for realizing the invention in its various embodiments.

Claims (15)

Claims 1. Device for extracting pollutant-laden air from the surface area of immersion baths for the surface treatment of workpieces, in particular their galvanizing, wherein a suction wall with an internal suction channel is carried along both sides of the immersion baths and the walls have inlet openings for the air to be extracted, characterized in that that on each suction wall (11) a blow pipe (16) extending over the length of the immersion tub (10) is arranged with blowing nozzles (19) directed over the surface of the bath. 2. Device according to claim 1, characterized in that the injection nozzles (19) are aligned parallel to the bath surface (18). 3. Device according to claim 1, characterized in that the injection nozzles (19) are aligned at an angle to the bath surface (18) with an upward direction. 4. The device according to claim 3, characterized in that the angle of attack of the injection nozzles (19) to the bath surface (18) is up to seventy degrees. 5. The device according to claim 3, characterized in that the angle of attack of the injection nozzles (19) to the bath surface (18) is between twenty and thirty degrees. 6. Device according to one of claims 1 to 5, characterized in that on the injection nozzles (19) aligned in the outflow direction of the air, sharp-edged guide plates (20) are arranged, through which the blown air flows away. 7. The device according to claim 6, characterized in that the sharp-edged front edge of the guide plates (20) extends up to the vertically projected edge of the immersion tank (10). 8. The device according to claim 6 or 7, characterized in that the injection nozzles (19) along the tube (16) as a continuous slot and the guide plates (20) are designed as a uniform longitudinal component. 9. Device according to one of claims 1 to 8, characterized in that the suction walls (11) are arranged to spring back upwards from the edge of the immersion bath and the injection nozzles (19) at the end of the arms (17) bridging the recessed distance and connected to the tube (16) ) are arranged. 10. The device according to claim 9, characterized in that the arms (17) are pivotable about the longitudinal axis of the suction wall (11). 11. The device according to claim 9 or 10, characterized by a with the blowpipe (16) connected over the length of the immersion trough (10) leading flap (17) with injection slot (19). 12. Device according to one of claims 1 to 11, characterized in that the suction walls on both sides (11) have a device for adjusting the height of the blowpipe (16) with arms (17). 13. The apparatus according to claim 12, characterized in that the carrier (15) with blow pipe (16) relative to the end strip (14) of the suction wall (11) is adjustable in height. 14. Device according to one of claims 1 to 13, characterized in that the above 5 10th 15. Device according to one of claims 1 to 14, characterized in that the amount of air blown in via the injection nozzles (19) is at most ten percent of the amount of air drawn off via the suction walls (11). 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5 15 20th 25th 30th 35 40 45 50 55 60 65 4th 7 CH676 808A5 Bath surface (18) and suction space (24) delimited by the suction walls (11) is shielded laterally and on the end faces of the immersion bath (10) by sealing plates (21).