DE4212164C2 - Process for the suction of air contaminations resulting from the production of chipboard and the like pressed parts and for cleaning the suction air flow from these contaminants and device for carrying out the process - Google Patents

Description

The invention relates to a suction and cleaning process ren according to the preamble of claim 1.

For suctioning and separating those that arise during die casting Such a procedure is described in the prospectus 924 from the company Keller Lufttechnik "suction and separation under pressure casting machines "from January 1991.

It has been shown that the application of such a wet separation system for suction and separation of air pollution such as those used in the operation of presses for the production of Chipboard is created (paraffins, resins, phenols, formaldehyde, evaporated press oil, wood particles etc.), not the desired result.

DE 36 35 934 A1 describes a method and a device device for the purification of raw gas, in particular with phenol and / or Formaldehyde and / or its condensation products are contaminated tem exhaust gas from a mineral fiber production plant, known. Here the raw gas is circulated, with micro organically enriched washing liquid in a spray tower sprayed and in this way part of the raw gas bound impurities. The through the spray tower continuous aerosols are discharged in a high voltage field separated and the separated impurities from biologically oxidized the microorganisms.

This process is based on the principle of the so-called bio washing in connection with an aerosol separation by High voltage field.

The invention has for its object a suction and cleaning delivery method according to the preamble of claim 1  going to improve that pollutant complexes of those mentioned Kind extensively eliminated and by avoiding pollutants Deposits in the piping ensure the operational safety of the Suction system is increased.

This object is inventively by the measures in the kenn drawing part of claim 1 solved.

In addition to eliminating the risk of fire, he ensures that inventive methods also improved emissions protection.

Further developments and expedient refinements of the invention are characterized in the subclaims.

The invention is explained below with reference to the drawing tert, which is an embodiment of a system for suction of gases and vapors as well as small particles and for cleaning suction air flow in a chipboard press illustrated mathematically.

As can be seen from the drawing, the chipboard 10 is pressed together, for example by means of a press ( 13 ) containing two continuous metal belts ( 11 , 12 ) at the appropriate temperature and with the necessary pressure. Via the detection elements ( 15 ) installed in the structural unit ( 14 ) with the connecting lines ( 39 ), the downstream flow nozzles ( 16 ) and the feed line sections ( 17 ) pass through the suction fan ( 18 ) designed as a radial fan and exhaust gases and Vapors and the small particles sucked from the edges of the chipboard ( 10 ) into the suction line ( 19 ). The gases and vapors mainly consist of fats, paraffins, resins, phenols and formaldehyde.

By means of a pump ( 21 ), washing liquid is fed from the reprocessing basin ( 20 ) in the system ( 28 ) via the feed line ( 32 ) into the distributor line ( 23 ), each of which is proportionately fed into the pre-nozzles ( 22 ) 16 ) arrives and is injected into the suction line ( 19 ). As a result, the suction air is cooled below its dew point temperature (saturation cooling), so that a large part of the gaseous and vaporous impurities condense out and form aerosol. At the same time, the suction line ( 19 ) is rinsed and kept free of deposits. The pre-nozzles also form an effective flame arrester in the event of pipe fires.

The separating zone ( 24 ) adjoining the structural unit ( 14 ) contains a droplet separator ( 25 ), upstream of which a main nozzle ( 26 ) is arranged, into which the suction line ( 19 ) on the one hand and the washing liquid distributor line ( 23 ) on the other hand, the If necessary, the supply of washing liquid can be adjusted or prevented by a gate valve ( 33 ).

In the main nozzle ( 26 ), the impurities in the exhaust air flow (non-air substances) are wetted intensively with washing liquid and bound to them. The washing liquid interspersed with the impurities is separated in the droplet separator ( 25 ) like that from the suction air flow, and the impurities (cloudy) are returned via a return line ( 27 ) to the reprocessing basin ( 20 ) of the system ( 28 ), in which the impurities are cleaned be separated again from the washing liquid. The heavy substances settle and are discharged with a sediment debris ( 34 ). The lighter substances form a floating sludge layer, which is transported with a sludge pusher ( 29 ) to a cleaning chain ( 38 ) and is also discharged through it. The liquid level in the reprocessing basin ( 20 ) is kept constant by level monitoring ( 30 ) in connection with an inlet fitting ( 31 ) and in the event of malfunctions with the help of an overflow.

The washer fluid pumped by the washer fluid pump ( 21 ) via the feed line ( 32 ) into the distributor line ( 23 ) is divided into two partial streams when the gate valves ( 22 ) and ( 33 ) are open, one of which strikes the main nozzle ( 26 ) and the other feeds the pre-nozzles ( 16 ).

According to a further idea of the invention, the impeller of the suction fan ( 18 ) is also sprayed with washing liquid which either runs from the reprocessing basin ( 20 ) in the Kreislaufver or is supplied separately as fresh liquid. Since caking on the fan impeller is avoided by any residual impurities still contained in the exhaust air flow. Furthermore, residual impurities are now wetted in the suction fan ( 18 ) with washing liquid and bound to it. In the suction fan ( 18 ) downstream droplet separator ( 35 ), the washing liquid with the contaminants is separated from the air flow again and runs through line 27 'into the reprocessing basin ( 20 ).

The cleaned exhaust air flows into the atmosphere via an exhaust air chimney ( 36 ) with an upstream silencer ( 37 ).

Due to the flexible design of the supply lines ( 17 ) and ( 17 ') to the suction line ( 19 ) and to the distributor line ( 23 ) for the liquid wash supply, the relief elements ( 15 ) with the respectively assigned pre-nozzle ( 16 ) and the associated gate valve ( 22 ) can be moved relative to each other if necessary.

An easily removable, possibly flexible, design of the pipelines between the detection elements ( 15 ) and the pre-nozzles ( 16 ) enables rapid removal of any deposits that may occur in this area.

To support the separation of air pollutants NEN can be fed into the suction line 19 from a reservoir by means of a pump 40 via a feed line 41 additives such as coagulants or emulsifiers. This expediently takes place in the swirling area in front of the main nozzle 26 . Furthermore, the washing liquid located in the reprocessing basin 20 can be supplied with oxidizing agents in order to bind any toxins or to neutralize them chemically.

If necessary, the washing liquid can be fed into the suction line 19 in a quantity-dependent manner and in terms of its temperature, depending on the degree of contamination and the temperature of the suction air.

Claims (7)

1. A method for vacuuming in the production of particle boards and the like pressed air pollutants, such as gases, vapors and small particles, and for cleaning the exhaust air flow from these contaminants, the elements extracted by means of a suction fan via detection air pollutants by injecting from a Reprocessing basins are bound to the washing liquid conveyed into the suction line by means of a pump and then the washing liquid permeated with the impurities is separated from the suction air flow by means of a droplet separator, fed to the reprocessing basin and the cleaned exhaust air is blown into the atmosphere via a blow-out duct, characterized in that in that the washing liquid is fed into a manifold (23) from the power part passes through pre-orifices (16) in the suction line (19) and at the same time flushing for cooling the G Ases and vapors traversed exhaust air below their dew point temperature is used and the other washing water partial flow opens together with the suction line ( 19 ) into a main nozzle ( 26 ) upstream of the droplet separator ( 25 ) and is used for intensive wetting of the impurities contained in the exhaust air stream . 2. The method according to claim 1, characterized in that the impeller of the suction fan ( 18 ) is sprayed with freshly supplied washing liquid or with circulating washing liquid and the washed-out impurities are separated from the suction air flow in a further droplet separator ( 35 ) and fed to the reprocessing basin ( 20 ). 3. Device for performing the method according to claims 1 and 2, characterized in that the presses ( 13 ) associated with the detection elements ( 15 ) with the respective associated pre-nozzle ( 16 ), the respective supply line connected to the suction line ( 19 ) ( 17 ), finally to the main nozzle ( 26 ) leading distributor line ( 23 ) form a structural unit ( 14 ) on which the main nozzle ( 26 ) and the droplet separator ( 25 ) containing separation zone ( 24 ) follows, one the reprocessing basin ( 20 ) is associated with a sediment dreamer ( 34 ) and a mud slide ( 29 ) equipped system ( 28 ), and that following the separation zone ( 24 ) one from the suction fan ( 18 ) with its impeller and the wide Ren droplet separator ( 35 ) and the exhaust air chimney ( 36 ) with this upstream silencer ( 37 ) containing the structural unit ( 38 ) is provided. 4. A device for performing the method according to claim 3, characterized in that the detection elements ( 15 ) with the respectively associated pre-nozzle ( 16 ) and the associated gate valve ( 22 ) by flexible design of the supply lines gene ( 17 , 17 ') to the suction line ( 19 ) and to the distribution line ( 23 ) for the washing liquid supply are displaceable relative to one another. 5. Device according to claim 3, characterized in that the connecting lines ( 39 ) from the detection elements ( 15 ) to the pre-nozzles ( 16 ) are easily removable. 6. Device according to claim 5, characterized in that the connecting lines ( 39 ) from the detection elements ( 15 ) to the pre-nozzles ( 16 ) are flexible. 7. Devices according to claims 3 and 4, characterized in that the suction fan ( 18 ) is designed as a radial fan.