DE3743714C1 - Extraction device - Google Patents

Abstract

In a device for extracting air charged with harmful substances from the surface region of immersion baths for the surface treatment of workpieces, in particular their galvanising, at least one extraction wall with an internally lying extraction duct being taken laterally along the immersion tank and the wall having inlet openings for the air to be extracted, the extraction of the air charged with harmful substances and the sealing off to the surrounding atmosphere of the extraction space existing above the bath surface are to be improved. To this end, it is envisaged that there is arranged on the extraction wall (11) a blow pipe (16), which runs over the length of the immersion tank (10), with injection nozzles (19) directed parallel to the bath surface (18). <IMAGE>

Description

The invention relates to a device for suction polluted air from the surface area of immersion baths for the surface treatment of works pieces, in particular their galvanizing, being longitudinal the immersion tubs have a suction wall on both sides is carried with an internal suction channel and the Walls inlet openings for the air to be extracted exhibit.

A suction device with the aforementioned features is in the publication DE-Z. "Building technology-building physics- Umwelttechnik "gi, issue 11/1979, page S 10/340 bis S 14/344; at the suction shown there device is a bilateral edge suction hit by going to both long sides of the dip pan a suction wall is arranged over which the rising polluted lut is sucked off. This has the disadvantage that considerable  Air volumes sucked out through the extraction walls on both sides and must be led away to the thermal Air drive from the bathroom surface into the suction channels redirect; consequently the efficiency is such insufficiently designed facilities.

In the same publication there is also a suction concept described, in which on one long side the immersion tub blowing and on the opposite A suction hood is arranged along the side, so that a parallel to the bathroom surface and that Bad supposedly shielding blow jet generated and captured by the exhaust hood and led away becomes. This has the disadvantage that due to the straight flow course considerable flow speeds must be generated in order to shielding the bathroom surface and redirecting the thermal to achieve conditional buoyancy on loaded lut; a satisfactory suction effect is with one such suction device also not to be reached.

The invention is therefore based on the object Suction device with the generic features to improve so that the rising pollutant polluted air as completely captured and over the suction walls can be cleaned, where at the same time the one to be taken for the suction Keep effort within reasonable limits.

To solve this problem is according to the main claim provided that on each suction wall over the length the blowing tube with parallel to the Bath surface directed injection nozzles is arranged. Advantageous refinements and developments are  specified in the subclaims.

The advantage of the invention is that the the rising of pollutants due to thermal effects Air column to be contrasted and the polluted air leading into the laterally arranged suction channels Reverse current in atmospheric air kept low can be done by blowing in the side openings blown air into one in the direction of the suction channels directed air vortex that favors the redirection of the air column.  

This advantage according to the invention is reinforced by that at the injection nozzles also parallel to the bathroom Surface-oriented sharp-edged baffles arranged are, on the one hand, due to the effects they cause hydraulic contraction of the ascending burdened Air column and on the other hand by a targeted Formation of a blowing air vortex hydraulically effective outlet cross-section for the polluted air reduced above the metal bath, which also caused by this hydraulically effective outlet cross-section portion of sealing air to be led is reduced.

The invention has a particularly advantageous effect that corresponding suction on both sides of the immersion bath walls with blowpipes are carried because on this way the blowing air directed towards each other flows and baffles to narrow the hydrau lisch effective outlet gap between the suction walls complement, so that the share of through this Aus sealing air to be guided must be kept small can.

Generally there has been a ratio of the share of over the air to be blown in and the sealing air from one tenth to nine tenths based on the total volume of extracted air as the optimal upper Limit for the measurement of the amount of blowing air posed.

With a view to advantageous practical application the baffles of the invention should not be closer than reach the vertically projected edge of the immersion bath, to free access to the diving tank over its entire  Ensure width; on the other hand, they should Baffles this position with regard to the least possible hydraulic outlet cross section for the have polluted air.

So far as the suction walls a recessed, have a funnel-shaped design, the injection nozzles have shown to be advantageous to be arranged on arms connected to the blowpipe the distance of the blowpipe caused by the recess compensate from the edge of the immersion bath and the injection nozzles bring it back into the optimal position. To here the It is after one to improve access to the diving tub preferred embodiment of the invention advantageous the arms swing around the longitudinal axis of the suction wall arrange bar so that the entire free opening space along the recessed suction walls for access to the immersion bath is available.

It is also advantageous to use the injection nozzles as one slot extending over the entire length of the blowpipe to perform on a pivoting flap and a single Baffle with a continuous tear-off edge in front to arrange.

In the drawing are exemplary embodiments of the invention reproduced, which are described below. It shows

Fig. 1 a suction device in a schematic sectional view,

Fig. 2 in a diagrammatical representation of a suction wall with a blowing head,

Fig. 3 shows the device of FIG. 1 with a schematically indicated air duct.

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

On a top of the suction wall 11 end bar 14 , a blow pipe 16 is arranged on supports 15 ; 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 embodiment shown in Fig. 1 position, the arms 17 are aligned from the exhaust wall 11 to the dip tank 10 and parallel to the surface 18 a in the dip pan 10 located metal bath, in particular the zinc bath. At the front end of the arms 17 there are injection nozzles 19 and in each case 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. In view of sealing of the sides of the above the dip pan 10 24 in the area of support 15 are vogesehen under the sparging arms 17 extending sealing plates 21 by the Absaugwände 11 with attached blowing device 16, 17 Absaugraumes formed, which in a not easily Darge manner for the sealing of the end faces of the immersion tub 10 are set up.

To use the entire, between the suction walls 11 available space above the immersion pan 10 for operations so the arms 17 are pivoted at an angle of two hundred and seventy degrees around the longitudinal axis of the associated suction wall 11 so that they from the operating position can be converted into an additionally shown rest position; For this purpose, the blowpipe 16 with arms 17 attached to it can 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 gear motor 23 are arranged at the ends of the blowing pipe 16 carried over the elongated immersion trough 10, and on the other hand a gear motor 23 by means of which the blowing pipe 16 can be pivoted with arms 17 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 bath 10 can be coated with blowing air.

The device shown has the following effect during operation of the immersion tank: From the suction chamber 24 formed between the suction walls 11 , the pollutant-laden air, which rises from the surface of a metal bath, for example by four hundred and fifty degrees Celsius, is sucked into the suction wall 11 through the inlet openings 13 and fed from here to 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 deducted in half via 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 ascending 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 guide plates 20 guided by blowing air, which together with the sealing air, the gap 25th hydraulically closed.

In Fig. 3, the resulting air flow is indicated in a schematic line; Due to the suction effect emanating from the suction walls 11 , the blowing air blown in parallel to the bath surface 18 via the guide plates 20 is deflected into the suction chamber 24 and induces a circular vortex 26 there , via which the air to be extracted is guided to the inlet openings 13 in the suction walls 11 on both sides . Between the areas covered by the vertebrae 26 parts of the impending above the bath 10 thermal column is only a limited space, must be what sealed off, and in this space flows under the suction of Absaugwände 11 effectively now still required sealing air thermals column opposite direction into the suction 24 and is also deflected like a vortex 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 exchange 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, at the same time the total amount of air to be extracted from the suction space 24 is considerably reduced ; at the same time, the efficiency of locking the suction chamber 24 against the ambient atmosphere is significantly improved. It has been found 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.

Claims (10)

1.Device for extracting polluted air from the surface area of immersion baths for the surface treatment of workpieces, in particular their galvanizing, whereby along both sides of the immersion tubs a suction wall with an internal suction channel is carried along and the walls have inlet openings for the air to be extracted , characterized in this way is characterized in 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 parallel to the bath surface ( 18 ). 2. Device according to claim 1, characterized in that on the injection nozzles ( 19 ) parallel to the bath surface ( 18 ) aligned sharp-edged baffles ( 20 ) are arranged over which the blown air flows away. 3. Apparatus according to claim 2, characterized in that the sharp-edged front edge of the guide plates ( 20 ) reaches up to the vertically projected edge of the immersion tank ( 10 ). 4. Apparatus according to claim 2 or 3, characterized in that the injection nozzles ( 19 ) along the tube ( 16 ) as a continuous slot and the baffles ( 20 ) are formed as a uniform longitudinal component. 5. Device according to one of claims 1-4, characterized in that the suction walls ( 11 ) from the immersion tub edge arranged recessed upwards and the injection nozzles ( 19 ) bridging at the end of the recessed distance, with the tube ( 16 ) connected arms ( 17 ) are arranged. 6. The device according to claim 5, characterized in that the arms ( 17 ) are pivotable about the longitudinal axis of the suction wall ( 11 ). 7. The device according to claim 5 odser 6, characterized by a with the blow pipe ( 16 ), over the length of the immersion pan ( 10 ) leading flap ( 17 ) with injection slot ( 19 ). 8. Device according to one of claims 1-7, characterized in that the above the bath surface ( 18 ) and through the suction walls ( 11 ) limited suction space ( 24 ) laterally and on the end faces of the immersion pan ( 10 ) by shielding plates ( 21 ) shielded is. 9. Device according to one of claims 1-8, 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 ). 10. Device according to one of claims 2-9, characterized in that the gap ( 25 ) between the opposite guide plate ends ( 20 ) corresponds to the width of the immersion tank ( 10 ).