DE202006002505U1 - Apparatus for purifying waste air streams containing volatile organic compounds comprises a rotary adsorber, a catalytic combustion unit and a heat exchanger - Google Patents

Abstract

Apparatus for purifying waste air streams containing volatile organic compounds comprises a rotary adsorber (3) whose inlet surface is divided into an adsorption sector (4), a regeneration sector (5) and a cooling sector (6), a catalytic combustion unit (8) and a heat exchanger (9) for preheating air for desorption.

Description

The The invention relates to a compact system for cleaning VOC-contaminated exhaust air flows (VOC: Volatile Organic Compounds), their application for both offers low as well as high emission concentrations.

VOC compounds come often in the form of solvents in paints and varnishes, in detergents, in personal care products, but also as Blowing agent in spray cans for use. In addition, they enter into printing and coating companies and in the production of fibers, Films and imitation leather on; but also plants for cleaning or for soldering electronic components emit VOC's. If VOCs get into the air, then they have partial a directly damaging Effect on humans and the environment (for example, the carcinogenic Benzene); above all, they act as so-called precursors in the formation of ground-level ozone.

For now finds a tightening the legal regulations for such emissions take place. The industry tries by conversion on water-soluble products (eg colors), by switching to products with much less VOC content and by installing more efficient exhaust air purification systems to meet these demands.

common Feature of said exhaust air streams is a mostly low concentration of pollutants that also in a larger temporal Range of large volume fluctuations are subject. Size airflows with low pollutant concentrations are only with greater effort to clean. For environmental protection it is necessary in the future, such emission currents clean off. Efficiently feasible technical possibilities, which correspond to these peculiarities are currently not available.

at on the other hand, some production processes also occur at times high concentrations, for. B. if, regular cleaning processes with solvents carried out Need to become or after the stoppage of production the operating parameters of producing plants have not yet been reached. For this high VOC concentrations are currently used exhaust air purification systems normally not designed.

It It is known that low concentrations are preferred by biological Exhaust air purification with organic scrubbers adsorbed. bioscrubber however, require a nearly constant concentration level without Interruption of the production process. The long-term effectiveness is difficult to estimate and conversions to other solvent systems are not feasible in the short term.

other Procedures such. As condensation, exhaust air, TNV (thermal afterburning) and RNV (regenerative afterburning), however, are only at higher concentrations operate with reasonable effort. In addition, in the technologies the post-combustion (RNV, TNV) additionally burned fossil fuels.

The still widely used cleaning technology for the purification of solvent-loaded exhaust air with cyclically operated activated carbon filters does not correspond anymore the latest technology. Carbonaceous adsorbents tend to smoldering fires, if no inertization, z. With nitrogen, is carried out, what when retrofitting Old systems is problematic.

In EP 0920900 is described a rotor for concentration, with different circuit variants can be used for the air duct. The air flows are regulated with each other so that an optimal adsorption takes place. But even with this optimization, a complete separation of high concentrations is not possible.

To a solution according to WO 9936158 the desorption air flow is reduced and thus the expense for the aftertreatment, z. B. in a KNV (catalytic afterburning) reduced. Of the used rotor consists of an inner cylinder and an outer ring, so that the desorption segment is also divided into two parts small segment and a larger segment of the outer ring. In the first phase, the desorption air is through the larger segment guided.

Of the Desorbed air flow is then sorbed in the inner cylinder again and in the second phase with a small desorption air stream Desorbed by the inner, small segment again. The factor of Concentration should be up to 400 times. By the absence a cooling zone can but no high desorption temperatures are used to solvent Desorb with high boiling point.

To US 5167679 Attempts to increase the effectiveness of a cleaning system by the series connection of two rotors whose diameter and rotational speeds are preferably different. Essential to the invention is that the direction of rotation of the two rotors is opposite. By using a second rotor, the performance of the system is increased sustainably, but on the other hand there are the additional costs for this rotor.

disadvantage all known solutions is that big airflows with low pollutant concentrations only with greater effort to be cleaned.

task The invention is to overcome this disadvantage of the prior art remove; In particular, it should be possible to have a large concentration range of solvent emissions to be cleaned up with comparatively little plant-technical expenditure.

These The object is achieved by the features listed in claim 1, the combination a module for the enrichment of pollutants with a catalytic Afterburning plant, solved. Advantageous embodiments of the invention the claims 2 to 4 are taken.

To proviso The invention readily addresses the practical VOC cleaning requirements adaptable Compact system before, the essential components of a rotor adsorber for Concentration of VOCs and a KNV (catalytic afterburning) system for oxidation. This can be done eliminating the concentrated VOC's. At a Optimized desorption concentration, the system works autothermally, d. h., the catalyst does not have to be heated additionally. By the change the enrichment factor and the use of heat exchangers can according to the invention an energy-optimal Driving can be achieved even at low input concentrations. The system is running after adaptation to the local Exhaust air conditions automatically.

The compact VOC exhaust air purification system can be flexible and individual when retrofitting of old plants (eg paint shops, printers, coating plants, Fiber production, artificial leather processing, soldering processes), but also in the Soil remediation (eg at petrol stations, chemical plants, barracks, Airfields) in landfill aftercare, bottling and refilling processes and in the electronics industry be used.

Advantageously, the developed compact system can be used in the cleaning of VOCs even in the cases where initially considered activated carbon plants due to lower prices for the activated carbon again economically competitive. Here, however, as a result of the fact that such systems do not have sufficient separation efficiency, the plant according to the invention is an outstanding alternative. This is z. As in vinyl chloride, dichloromethane and cis-1,2-dichloroethene as well as in the simultaneous adsorption of low volatility VOCs and at high humidity of the case. It should also be borne in mind that disposal of loaded activated carbon creates an additional CO ₂ burden on the environment.

The Advantages achieved by the invention are that both Both low and high concentrations are equally effective in harmless products being transformed. It is particularly advantageous that in this case no additional energy resources must be used. Through the use of heat exchangers and by the regulated increase The concentration is also a particularly ecological way of driving the system possible.

The Invention is based on an embodiment explained in more detail; For this In the attached figure, the VOC exhaust air purification system according to the invention shown schematically.

It can be seen that the process air flow ( 1 ) from Z. B. 300 m ³ / h with a frequency-controlled process air fan ( 2 ) is sucked. The VOCs are stored in a rotor adsorber ( 3 ) adsorbed. The inflow sectors in the rotor are divided into three parts. 10/12 of the area is intended for adsorption and 1/12 each for regeneration and cooling. The adsorption sector ( 4 ) turns into the regeneration sector with an optimizable rotor speed ( 5 ) and then into the refrigeration sector ( 6 ). By the on z. B. heated 130 ° C Regenerierluftstrom ( 7 ) the adsorbed VOCs are desorbed. With the volume flow ratio process air flow ( 1 ) to Regenerierluftstrom ( 7 ) (eg 300 to 50 m ³ / h) the enrichment factor is set. With an enrichment by a factor of 6 increases the inlet concentration of the process air of z. B. 0.5 g / m ³ to a VOC Desorptionskonzentration of 3.0 g / m ³ VOC. This concentration is used by the catalyst of the catalytic post-combustion plant (KNV) ( 8th ).

At 400 ° C, the VOCs burn almost completely to CO ₂ and water. The heat of combustion at a concentration of 3 g / m ³ VOC ensures that the catalyst no longer needs to be heated. The KNV works autothermally. The heat energy of the hot exhaust air of about 150 ° C is in the following heat exchanger ( 9 ) to the regeneration air flow ( 7 ), so that the heater ( 10 ) only has to reheat in the start-up phase.

At lower inlet concentrations, the degree of enrichment can be increased so that an autothermal operation of the KNV ( 8th ) is achieved. At higher inlet concentrations, adsorption in the rotor ( 3 ) makes no sense, because at a separation efficiency of 90%, the clean air concentration is exceeded inadmissibly. In this case, according to the invention, the process air flow ( 1 ) and directly to the KNV ( 8th ). For this purpose, the inlet concentration is continuously with a gas sensor ( 11 ). At a concentration of> 1 g / m ³ , the controller ( 12 ) the By pass valve ( 13 ) and the valve in the regeneration air flow ( 14 ) and in the process air ( 15 ) closed. The cooling air fan ( 16 ) and the heater ( 10 ) are turned off. Since the volume flow for the KNV ( 8th ) is too high, the process air flow ( 1 ), if procedurally possible, reduced by half to 150 m ³ / h. As a result, the concentration is twice as high, whereby the VOC's can be advantageously burned almost autothermic. When the inlet concentration decreases again, it returns to normal operation.

By way of example, for a process air flow of 2000 Nm ³ / h for inlet concentrations up to 500 mg / m ³ VOC, an outlet concentration on the rotor of <50 mg total C / m ³ can be achieved. The degree of separation is>90%; the enrichment is 6-10 times. The desorption temperatures are up to 180 ° C. The attainable degree of purification of the KNV is>98%; the exit concentration in the KNV is <50 mg total C / m ³ . The necessary connection capacity of the system according to the invention would be 30 KW in this example, the energy consumption during autothermal operation being max. 4 W / m ³ would reach. The dimensions of such a system could be adapted to a 10 foot container.

the pointed example could also other modules, such. B. a fine cleaning with activated carbon assigned become. In the case of the purification of chlorinated or fluorinated VOCs, it is expedient to Elimination of hydrogen chloride or hydrogen fluoride, which is in the catalytic afterburning forms a wet scrubber module downstream, controlled by an appropriate gas detection technology becomes.

1

Process air flow

2

Process air fan

3

Rotoradsorber

4

adsorption sector

5

regeneration sector

6

cooling sector

7

Desorption / Regenerierluftstrom

8th

catalytic Post-combustion plant (KNV)

9

heat exchangers

10

stoker

11

gas sensor

12

regulator

13

Bypass valve

14

Valve in Regenerierluftstrom

15

Valve in the process air

16

Cool air fan

Claims (4)

Exhaust air purification system for cleaning VOC-contaminated exhaust air streams, characterized in that a module for the enrichment of pollutants, consisting of a rotor adsorber ( 3 ), whose inflow surface into three sectors ( 4 ; 5 ; 6 ) is divided for adsorption, regeneration and cooling, with a catalytic afterburning plant ( 8th ), one or more heat exchangers ( 9 ) arranged downstream of the exhaust duct of the catalytic afterburning plant ( 8th ), for preheating the desorption air ( 7 ) are used. Cleaning system according to claim 1, characterized in that the sector for adsorption ( 4 ) 10/12 (ten twelfths), the sector for regeneration ( 5 ) and the sector for cooling ( 6 ) each 1/12 (one twelfth) of the inflow surface of Rotoradsorbers ( 3 ). Cleaning system according to claim 1 and 2, characterized in that it has measuring and switching technology, especially a gas sensor ( 11 ), a controller ( 12 ), a bypass valve ( 13 ), in the regeneration air stream ( 7 ) and one in the process air stream ( 1 ) switched valve ( 14 ; 15 ), which allows the catalytic afterburning plant ( 8th ) directly with the process air stream ( 1 ). Cleaning system according to claim 1 to 3, characterized in that the system is a controller ( 12 ), which determines the amount of exhaust air to the maximum allowable amount of exhaust air through the catalytic post-combustion system ( 8th ), adapted so that the concentration in the exhaust air is increased so that an autothermal combustion takes place.