DE20203378U1 - Device for shielding openings in a landfill - Google Patents

Abstract

Device comprises at least two core air jet nozzles (6) arranged in different edge regions of an opening and connected to an air blower (1). The outlet openings of the core air jet nozzles are directed in the direction of the opening so that the core air jets (9) produced by the core air jet nozzles are directed through the opening into the refuse depot from different directions at an angle of 1-60degrees. Preferred Features: The core air jets produced by the core air jet nozzles are directed through the opening into the refuse depot at an angle of 15-35degrees. Two core air jet nozzles are arranged on opposite-lying or adjacent sides of the opening.

Description

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04.03.2002 SC/se 620060G

Airwalltechnology GmbH
Erftstr. 20

D-41238 Mönchengladbach

Device for shielding openings of a waste disposal site

The invention relates to a device for shielding openings, in particular gates or doors of a waste disposal site. It particularly relates to a device for shielding openings of unloading points, loading or receiving bunkers or other facilities for the delivery, transport and storage of waste.

When shielding such landfills, it is particularly important to take into account that they are regularly frequented by landfill vehicles. According to the thirtieth regulation for the implementation of the Federal Immission Control Act, the emission of dust and odors from the materials stored in the landfill during the vehicle dumping process must be prevented. To this end, the aforementioned implementing regulation provides for the installation of building locks at the landfill areas. This means that a loaded vehicle must first drive backwards into the lock, then the front lock gate closes and only then does the actual landfill bunker gate open. This procedure involves a considerable amount of work and time.

During the tipping process, the vehicles often have to run their combustion engines at high speed in order to keep the vehicle's internal hydraulics functioning. This means that the driver of such a vehicle is constantly exposed to the risk of poisoning from exhaust gases (CO ₂ ).

In order to avoid this health hazard and not to exceed the so-called MAK values, very expensive large ventilation systems would have to be installed in the pre-lock area in order to protect the driver from poisoning by sufficiently flushing the room with fresh air.

The object of the present invention is therefore to create a structurally simple, inexpensive to manufacture and easy to handle device of the type mentioned at the beginning, which offers a permanently safe and effective shielding of the environment against internal and harmful air conditions such as dust and odors and which at the same time enables a simple and quick dumping process into the waste disposal site without undermining the conditions required by the Federal Immission Control Act.

This object is achieved according to the invention by a device according to claim. Advantageous embodiments and further developments of the invention emerge from the dependent claims.

It is essential in the solution according to the invention that at least two core air jet nozzles are provided, which are arranged in different edge regions of the opening and are connected to an air blower, the outlet openings of which are directed in the direction of the opening in such a way that the core air jets emerging from the core air jet nozzles are directed from different directions at an angle between 1° and 60° through the opening into the waste disposal site.

The main advantage is that locks with the aforementioned disadvantages are no longer required. Rather, the device according to the invention creates a cost-effective shield for waste disposal sites, which in particular also shields contours in the room dividing opening, for example the contour of an unloading vehicle, safely and effectively against internal and harmful air conditions such as dust and odors. The laborious opening and closing of several lock gates during tipping processes is no longer necessary.

The device according to the invention is simple in design and can be manufactured inexpensively and is easy to assemble and handle. In particular, the fact that the pre-lock previously required for shielding can be omitted leads to considerable cost savings for the operator of a landfill.

Devices for generating air curtains or air curtains are well known. Their application ranges from door to gate air curtain devices for shielding rooms or building halls. These shielding devices usually have a closed housing, which can contain fans and heating registers and create this air curtain using grilles or slats. The reason for such applications is usually to shield cold air or to heat the incoming cold air.

The known designs have high air and heating outputs, which generally make the operation of such devices uneconomical, as they generate turbulent flow behavior. This leads to so-called turbulence clouds being blown into or out of the building by incoming cold air or other forces, e.g. drafts, and thus the lower area of such a door opening offers unhindered entry to the incoming cold air (wind).

In addition, with such conventional air curtain systems or air curtains, the air blown out is limited to the contour of the vehicle at most. So-called air shadow spaces remain underneath the tipper, through which odorous and dust-laden air from the landfill bunker can escape unhindered into the ambient air.

Such a system for generating air curtains or air screens cannot therefore be used for the legally required shielding of waste landfills.

In contrast, it is particularly important in the device according to the invention that the air exits from at least two different directions and that the air flows into the landfill building to be shielded. This means that not only the landfill opening itself, but also the contour of a vehicle located in the opening and the spaces underneath a tipper or underneath the vehicle axles can be detected and safely sealed off.

The device according to the invention uses the so-called "Coanda effect" so that the air jets that impinge on the vehicle contour at an angle cling to the vehicle at a certain angle and flow along the vehicle contour into the building. The previously calculated air volume of this jet prevents the dust and odor-laden air from escaping and, since it is outside air, dilutes the odor-laden air inside the landfill, which in turn benefits the installed exhaust air purification system.

It is particularly advantageous if the core air jets emerging from the core air jet nozzles are directed at an angle of 15° - 35° through the opening into the waste disposal site. This allows particularly safe and effective shielding to be achieved.

According to a particularly preferred embodiment of the invention, two core air jet nozzles are arranged on opposite sides of the opening. The lateral core air jets are advantageously each formed by an extremely high, narrow flat jet.

According to an alternative embodiment of the invention, two core air jet nozzles can also be arranged on adjacent sides of the opening. In this case, too, effective shielding can be achieved because the air jets are blown out from different directions.

It is also particularly advantageous if the core air jet nozzles extend over the entire height or width of the opening. This provides optimal shielding of the landfill opening and reliably prevents odorous or dust-laden air from the landfill bunker from escaping into the ambient air.

A particularly effective shielding can further be achieved in that the core air jet nozzles each comprise a rectifier channel for calming the introduced air flow into a laminar outflow of a core air jet at the outlet opening.

Advantageously, the core air jet nozzles can also comprise a guide plate for guiding the core air jet with low turbulence.

It is also particularly advantageous if the core air jet nozzles are arranged so that they can pivot about an axis that runs parallel to the respective edge area of the opening. This creates a particularly flexible, adjustable device that can be adapted to different applications.

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Preferably, it is proposed that the core air jet nozzles are connected to the air blower at the front or side. Several core air jet nozzles can be connected to a common air blower via connecting lines or each core air jet nozzle can be connected to a separate air blower.

Preferably, the intake opening of the air blower is connected to the environment so that outside air is sucked in.

Further advantages and features of the invention will become apparent from the following description and the embodiments shown in the drawings.

Show it:

Figure 1: Three-dimensional representation of a first embodiment of the device according to the invention;

Figure 2: Representation of the previous shielding of a waste landfill by means of a lock;

Figure 3: Three-dimensional representation of a second embodiment of the device according to the invention;

Figure 4: Sectional view of the device according to the invention showing the operating principle according to the invention;

Figure 5: Cross section through a core air jet nozzle according to the invention; Figure 6: Longitudinal section through a core air jet nozzle according to the invention.

The device according to the invention comprises an air blower 1, which sucks in outside air 2 on the suction side and is connected on the pressure side via a pipe system 3 to two core jet nozzles 6 located next to the gate opening 4 of a waste disposal site 5. The air blower 1, which by design must overcome a defined counterpressure, conveys fresh air on the suction side and presses the pre-compressed air into the nozzles 6, which in turn have a pressure chamber.

The pre-pressure prevailing here leaves the pressure chamber via a narrow blow-out nozzle, which is already adapted to the pressure housing A described. The nozzle itself is provided with a guide plate E inside the pressure box A, which follows the air direction parallel to it, so that the turbulent air inside the pressure chamber is channeled here and becomes laminar at a high speed. After leaving the nozzle, a flat core air jet is created, which has a very low induction with the secondary ambient air. In order to reinforce the so-called "Coanda effect", another guide plate C is arranged on the side of the pressure housing and parallel to the outflow direction, the length of which can be adjusted depending on the core jet length requirements (Figure 5).

Due to this physical effect, the highly accelerated exhaust air adheres to the airfoil and only breaks off at the end of this surface boundary (flow separation).

By arranging two core air jets according to the invention, areas with different physical or physical parameters, such as temperature, degree of air pollution, molecular odor load, and/or chemical air composition, can be separated or shielded from one another.

The core air jet nozzle shown in Figure 6 in longitudinal section and as a detail in Figure 5 in cross section has an air wall pressure linear module housing A,

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which can be made of plastic, steel or stainless steel. On the pressure side, it has a pressure connection B for an upstream blower. An adjustable air baffle C can optionally be provided for adjusting and optimizing the core jet. The adjustability of the external air baffle is shown at F. A downstream air straightener D for blowing out the laminar flow can have an M-shaped, Z-shaped, square or rectangular grid structure, which is also available as a purchased semi-finished product. An air duct E including an air catcher edge is molded on to convert the turbulent flow into a laminar flow. A base plate G is provided for the pivoting attachment of the pressure linear module to the floor. The adjustability of the base plate with a screw connection is shown at H. An optional pre-rectifier J can be arranged to calm the turbulent air flowing in from the upstream pressure blower.

In the embodiment shown in Figure 1, the pressure nozzles 6 on the side of the passage gate 4 are arranged so that they can pivot about a vertical axis. The mechanical adjustment of the basic setting angle of the pressure nozzles 6 is achieved with a fixed base plate and a bearing in the form of a collar that rotates on it. Both nozzles 6 are connected to a common air blower 1 via pipes 3.

In contrast, Figure 3 shows a variant arrangement in which the pressure nozzles 6 arranged at the side of the passage gate 4 generate an air jet that has a jet angle of 15 - 35° on the vehicle standing in the opening 4. Each nozzle 6 is connected to a separate air blower 1.

The solution according to the invention has two core air jet nozzles 6, each of which has a guide plate C which guides the core air jet with low turbulence. Furthermore, the device according to the invention comprises a specially designed

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High-pressure blower 1, which can be located outside the bunker 5 to be sealed off on the ground, on the roof or on the facade wall. This high-pressure blower 1 is connected on the pressure side to rigid or flexible connecting pipes 3, which can consist, for example, of spiral-seam pipe, plastic pipe or flexible aluminum pipe, which must have the necessary pressure resistance. The design parameters of the pressure blower 1, usually a radial fan, are between 600 and 4000 Pa, depending on the opening geometry to be sealed off.

The core jet nozzles 6 have a housing A, which can be folded on several sides, half-round and/or fully round. The housing, also referred to as the so-called pressure linear module A, is fed from the front from above or from the side or from below by means of a pressure blower 1, whereby the defined volume of this module has a pressure accumulation space on the one hand and forms a calming zone for the turbulently entering air on the other.

The integral rectifier channel E converts the turbulent air as a calming section into a laminar outflow at the nozzle end. In order to reduce the turbulence at the pressure inlet of the nozzle, a baffle housing can be arranged so that the air that is swirled in short pipe sections is forcibly converted into a straight-line flow.

The pressurized blower air in the storage area is captured by an inner baffle edge E and guided into the narrow nozzle channel. The inner baffle E and the angled edge are dimensioned depending on the degree of turbulence.

The pre-compressed air can advantageously pass through another rectifier D shortly before entering the nozzle, which passes through a grid structure with a square, rectangular, triangular, M-shaped, Z-shaped or trapezoidal cross-sectional geometry. The construction depth of this profile corresponds to 1.5 to 6 times the construction depth of the ratio of the nozzle width. After passing through the

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With an almost laminar exit jet from the nozzle, the core jet is positioned on the guide plate, which can be adjusted parallel to the outside, according to the "Coanda effect" and follows this flat surface, which also indicates the direction of the jet, to the defined separation edge. The separation edge is shaped as a quarter-round edge in order to minimize possible separation noise. The separation edge itself is shaped in order to induce the stagnant secondary air into the core jet due to the angle of the edge and thus minimize the molecular friction between accelerated air and stagnant ambient air (so-called injector effect or follow-through acceleration).

The guide plate length, which can be individually adjusted in length, has a length of 0.1 to 2 times the length of the flow straightener in the pressure nozzle. The length adjustment is preferably carried out using elongated holes clamped with screws or guide rails in the side edges or similar.

Figure 4 shows the flow path of the inward-directed outside air jet, which is applied to the exemplary vehicle body 7, follows the longitudinal axis and penetrates the air-polluted part of the building 5 as a radiation cone. As previously described, this brings fresh air into the odor- and dust-polluted bunker 5. This results in a dilution of the air concentration, which then also supports the exhaust air purification system that is necessarily installed.

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Claims (12)

1. Device for shielding openings 4 , in particular gates or doors, of waste disposal sites 5 , characterized in that at least two core air jet nozzles 6 are provided, which are arranged in different edge regions of the opening 4 and are connected to an air blower 1 , the outlet openings of which are directed in the direction of the opening 4 in such a way that the core air jets 9 emerging from the core air jet nozzles 6 are directed from different directions at an angle between 1° and 60° through the opening into the waste disposal site 5 . 2. Device according to claim 1, characterized in that the core air jets 9 emerging from the core air jet nozzles 6 are directed at an angle of 15°-35° through the opening into the waste disposal site 5 . 3. Device according to claim 1 or 2, characterized in that two core air jet nozzles 6 are arranged on opposite sides of the opening 4 . 4. Device according to claim 1 or 2, characterized in that two core air jet nozzles 6 are arranged on mutually adjacent sides of the opening 4 . 5. Device according to claim 3 or 4, characterized in that the core air jet nozzles 6 extend over the entire height or width of the opening 4 . 6. Device according to one of the preceding claims, characterized in that the core air jet nozzles 6 are connected to the air blower 1 at the front or side. 7. Device according to one of the preceding claims, characterized in that the core air jet nozzles 6 each comprise a rectifier channel E for calming the introduced air flow into a laminar outflow of a core air jet 9 at the outlet opening. 8. Device according to one of the preceding claims, characterized in that the core air jet nozzles 6 comprise a guide plate C for guiding the core air jet 9 with low turbulence. 9. Device according to one of the preceding claims, characterized in that the core air jet nozzles 6 are arranged to be pivotable about an axis running parallel to the respective edge region of the opening 4 . 10. Device according to one of the preceding claims, characterized in that several core air jet nozzles 6 are connected to a common air blower 1 via connecting lines 3 . 11. Device according to one of claims 1 to 9, characterized in that each core air jet nozzle 6 is connected to a separate air blower 1 . 12. Device according to one of the preceding claims, characterized in that outside air can be sucked in by the air blower 1 .