WO1990012252A1 - Air conditioning plant to extract an air current with a high volume and mass flow - Google Patents

Abstract

In an air conditioning plant to extract a current of used air from a building containing organic pollutants in gaseous or finely divided form, with at least one fan arrangement which is designed to convey quantities of the order of a few 10?5 m?3/h and forces the used air into the space outside the building against atmospheric pressure, the fan arrangement takes the form of a gas turbine in which at least 30 % of the used air flow is led through its burner chamber(s). Behind the gas turbine is fitted a heat recovery plant capable of extracting heat from the used air flow.

Description

Ventilation system for the discharge of an exhaust air flow linked to a high volume and mass flow

The invention relates to an air-conditioning system for discharging an exhaust air flow associated with a high volume and mass flow from a building, which is loaded with gaseous or fine droplet-shaped organic loads, with at least one fan device, which relies on delivery rates of the order of some 10 ⁵ m ³ / h is designed and promotes the exhaust air flow against the atmospheric pressure in the building exterior.

Such systems are e.g. needed in the automotive industry for the body painting systems, in which after the application of the paint on the

Bodies, there is a burn-in phase at elevated temperature, which is also associated with the evaporation of large amounts of paint solvents, which get into the environment with the exhaust air flow. Although the organic substances released in this way are not toxic and, to that extent, they are not harmful to the environment, they do - due to their olfactory effects - often cause considerable environmental pollution, which in view of the large amounts of exhaust air that occur in a larger coating unit can be up to 2 x 10 ⁶ m ³ / h, can be very disruptive in an area of several square kilometers.

Since such odor-causing substances are practically inaccessible to filtering out, the only practicable way to reduce the odor pollution in the vicinity of a coating unit as far as possible is the construction of large exhaust air chimneys with a height of

 100 m and more, the creation of which is associated with high costs and which generally also significantly disrupt the landscape.

The object of the invention is therefore to provide a ventilation system of the type mentioned, which is comparatively simple and space-saving

nevertheless an effective avoidance of one out of one

Loading of an exhaust air stream with organic substances ensures otherwise resulting odor nuisance.

This object is achieved in that the ventilation device comprises at least one gas turbine, through the combustion chamber (s) of which at least a portion of 30% of the exhaust air flow conveyed via the turbine is passed.

In addition to the - high - pumping effect, the gas turbine also conveys the function of a pollutant incineration plant, whose emissions are released into the atmosphere

Combustion products - essentially water and

Carbon dioxide - are odorless and therefore cannot develop any unpleasant smells in the environment. The system can be installed underground with a space-saving structure, so that the system is largely acoustically shielded from the outside world. As an outlet, an easily buildable structure is sufficient, the height of which, if it has to be arranged between factory buildings, hardly needs to be greater than that of the buildings arranged in the immediate vicinity.

In a preferred embodiment of the system according to the invention, the gas turbine is followed by a heat recovery system with which heat can be extracted from the exhaust air stream. This heat can advantageously be used to heat the hot air flow required in the context of a stoving paint system.

Both an air / air heat exchanger and an air / water heat exchanger can be provided as part of this heat recovery system.

It is expedient if these heat exchanger devices are arranged in a calming space in which the flow velocity is reduced to 1/10 to 1/50 the flow velocity with which the exhaust air flow exits the outlet nozzle of the gas turbine.

If, as provided in a special embodiment of the system according to the invention, the gas turbine has the structure of a known - single-stream (TL) air jet engine, the exhaust air is heated as much as possible Electricity and a corresponding extensive conversion of the cargo into odorless combustion products.

Alternatively, when converting the

Liquids in odorless end products, lower exhaust air temperatures are sufficient, the gas turbine also has the structure of a - also known - two-stream air jet engine, which is characterized by a particularly high delivery rate.

At least when the ventilation system is intended for permanent operation, it can be expedient if part of the drive power of the gas turbine is used to drive an electrical generator, which can supply a considerable proportion of the electrical base load required for operational facilities. If, on the other hand, the system is operated intermittently, it is advantageous if the generator is used to supply power to the electrical loads of the system itself.

Further details and features of the invention emerge from the following description of a special exemplary embodiment with reference to the drawing. This shows, in a simplified, schematic block circuit diagram, an installation according to the invention for removing and processing an exhaust air flow with a high value of the volume or mass flow.

The ventilation system shown in the drawing, designated overall by 10, is used to discharge a schematically represented by arrows 11 and 11 ' Exhaust air flow from a building room 12 into the atmosphere.

For the purpose of explanation, it is assumed that there is a paint shop (not shown) in the building space 12, by means of which a larger number of vehicle bodies are painted at the same time, the solvent contained in the paint by painting and "baking" the paint at elevated temperature evaporate, which are discharged with the exhaust air stream 11. In order to ensure adequate ventilation of a painting system, with which several hundred vehicles are painted every day, air flows of a few 100,000 m ² / h are required for large systems

2 x 10 ⁶ m ³ / h required, what, a conventional

Design of the supply air and extract air fans required in this regard as radial or axial fans, provided that a large number of such flow machines is required.

In the system 10, a stationary gas turbine 13 of a type known per se is provided as an exhaust air fan device, which drives a compressor 16 via a schematically indicated shaft 14, which compresses the exhaust air stream emerging from the building space 12 via an outflow nozzle 17 to the flow in the drawing only promotes combustion chambers of the turbine 13 represented by a combustion chamber symbol, where in the exhaust air stream 11 contaminated with the pollutants more gaseous or liquid

Fuel is introduced or injected, by the combustion of which the exhaust air stream 11 is heated to a temperature between 1200 and 1300 ° C., thereby greatly expanded and can drive the turbine 13.

In the combustion chambers 18 of the turbine 13, the substances taken up by the exhaust air flow 14 in the building space 12 are also burned to odorless gaseous substances, essentially water and carbon dioxide, so that they are finally released into the atmosphere

Exhaust air stream 11 'is free of substances which could otherwise lead to an unpleasant smell in the vicinity of the system 10.

In order to be able to use part of the heat of the exhaust air flow 11 'emerging from the turbine 13, a heat exchanger 19 is provided, which can be designed as an air-to-air heat exchanger, with which an air flow used for drying is heated and into which

Drying area of the painting system can be initiated, or as an air-to-water heat exchanger, possibly also as a combination of such heat exchanger systems, depending on the purposes for which the recovered waste heat is to be used.

The heat exchanger 19 also cools the exhaust air flow 11 ', which is desirable for reasons of the least possible disturbance to the microclimate in the environment of the operation used by the system 10.

The heat exchanger 19 is advantageously in one

- Not shown - Calming room, whose cross section flows through the exhaust air flow 11 ' area F _{2 is} significantly larger than the effective cross-sectional area F _{1 of} the - not shown - outlet nozzle of the turbine 13, so that the flow velocity v _{A of} the exhaust air flow 11 'is at least a factor F ₁ / F ₂ smaller than the exit velocity of the exhaust air flow 11' at the outlet nozzle of the turbine 13, but in practice still significantly lower, since, thanks to the cooling of the exhaust air stream 11 'in the heat exchanger 19 and the associated thermal "contraction" of the gas stream, a further reduction in the flow rate of the exhaust air stream 11' is achieved.

In a special design of the system 10 can

Turbine 13 can also be used to drive an electrical generator 21, which is particularly expedient when the system 10 is in permanent operation. It goes without saying that only a relatively small fraction of the total drive power generated by the turbine 13 should be "used" for driving such a generator 21.

The turbine 13 can be implemented in a manner customary for stationary turbines, e.g. in the textbook by Professor Dipl.-Ing. Willi Bohl "Flow Machines", structure and mode of operation, 1st edition,

Vogel Verlag, 1977, pages 137 to 140, explained.

The gas turbine 13 can also be implemented in a constructive analogy to air jet engines known from aviation technology, as in the aforementioned

Textbook on pages 140 to 143 presented and explained in detail. Here, a design of the turbine 13 in the manner of a single-flow air jet engine (TL) is preferable if the entire exhaust air flow 11 is to be heated to the temperature generated in the combustion chambers 18, while a design in analogy to a two-flow air jet Engine (ZTL), as can be seen on page 143 of the textbook mentioned, is particularly favorable if it is composed of a relatively cool bypass airflow and the "central" hot drive airflow which has been passed through the combustion chambers of the turbine 13, the resulting mixing temperature is sufficient to effectively convert the pollutants originally contained in the exhaust air stream 11 into harmless substances, in particular substances that do not lead to odor nuisance.

The design of the turbine 13 in analogy to such TL or ZTL air jet engines, which are known from aviation, is favorable, since such engines, with relatively small radial measurements, enable a high gas throughput, which is the case with large "engines" whose inlet nozzle has a typical clearance Has a diameter of 2 m, allow a volume flow of 2 x 10 ⁶ m ³ / h.

The design of the system 10 for an exhaust air flow with a volume flow of 10 ⁶ to about 2 x 10 ⁶ m ³ / h is therefore possible in principle with a single turbine 13, which has a structure analogous to a conventional two-stream air jet engine.

Claims

Claims 1. Ventilation system for the removal of a  a high volume and mass flow linked exhaust air flow from a building, which is loaded with gaseous or in fine droplet-like distribution organic loads, with at least one fan device, the flow rates of the Order of magnitude of some 10 ⁵ m ³ / h and promotes the exhaust air flow against the atmospheric pressure into the building exterior,  characterized in that the fan device comprises at least one gas turbine (13), through the combustion chamber (s) (18) of which at least a portion of 30% of the exhaust air flow (11, 11 ') is passed. 2. Ventilation system according to claim 1,  characterized in that the gas turbine (13) is followed by a heat recovery system (19) with which the exhaust air flow (11 ') Heat is removable. 3. Ventilation system according to claim 2,  characterized in that an air / air and / or an air / water heat exchanger (19) is provided as part of the heat recovery system. 4. Air conditioning system according to claim 2 or  Claim 3,  characterized in that the heat exchanger device (19) is arranged in a calming space in which the flow rate of the exhaust air flow (11 ') is 1/10 to 1/50 of the exit speed of the exhaust air flow (11') at the outlet nozzle of the gas turbine (13 ) is reduced. 5. Air conditioning system according to one of the preceding claims,  characterized in that the gas turbine (13) has the structure of a - known - single-flow air steel engine. 6. Ventilation system according to one of the preceding claims 1 to 4,  characterized in that the gas turbine (13) has the structure of a - known per se - two-stream air jet engine. 7. Ventilation system according to one of the preceding claims,  characterized in that part of the drive power of the gas turbine (13) is used to drive an electric generator.