DE102016209184A1 - Device for separating exhaust gases containing particles - Google Patents

Abstract

The invention relates to a device for separating exhaust gases containing particles, in which a raw gas containing particles is guided by means of a compressor via a tubular conduit whose at least one outlet opening in a closed container, to which a filter chamber is connected. In the container, an inert material in particle form as a loose bed, an inert liquid or a suspension of an inert material in particulate form and the outlet opening (s) or at least one outlet opening of a dip tube opens / open into the outlet opening (s) of the tubular conduit within inert material, inert liquid or suspension. From the inert material, the inert liquid or the suspension escaping raw gas is in the vertically above the container arranged filter chamber in which at least one filter element is arranged out. The clean gas exiting through the at least one filter element is discharged into the environment or recirculated during processing.

Description

The invention relates to an apparatus for separating exhaust gases containing particles. It is particularly suitable if chemically reactive particles are contained in the respective raw gas. This is the case, for example, when processing titanium or titanium alloys. Thus, in the generative production of components, such as, for example, the selective melting of powdered materials with an energy beam, in particular a laser beam, both solid particles or particles formed from the vapors by phase changes are contained in the liberated vapors. Since the respective particle size can be very small, their chemical reactivity has a particularly disadvantageous effect and can lead to combustion, to deflagrations and possibly even to small explosions which, however, are to be avoided. In particular, when chemically reactive components are released during processing, it is possible to work in an inert atmosphere. The inert gas used can also be passed through the device according to the invention for the separation. But it is also possible to separate under normal atmospheric conditions without inert gas.

The generative manufacturing process is used in particular in the processing of chemically reactive materials in an inert atmosphere. Often, this is argon because of the increased safety and low impact on the materials used to make it. Because of the high cost of the argon used, recycling is useful.

However, it is not completely safe to adhere to the argon atmosphere at any time during the separation of the particles contained in the raw gas, so that critical situations can not always be avoided. This concerns in particular times when collecting containers for separated particles are to be removed from a device or replaced and then no inert conditions can be met, which avoid self-ignition or other chemical reaction of particles.

It is therefore an object of the invention to provide options for a clean, safe and safe separation of particles from a raw gas.

According to the invention, this object is achieved with a device having the features of claim 1. Advantageous embodiments and further developments of the invention can be realized with features described in the subordinate claims.

In the inventive device for a separation of exhaust gases containing particles, a raw gas containing particles is guided by means of a compressor via a tubular conduit whose at least one outlet opening in a closed container, to which a filter chamber is connected. The raw gas may be an inert gas, in particular argon or a mixture with air.

The container contains an inert material in the form of particles as a loose bed, an inert liquid or a suspension of an inert material in particle form. The outlet opening (s) of the tubular conduit or at least one outlet opening of a dip tube into which the outlet opening (s) of the tubular conduit terminate is / are arranged within the inert material, the inert liquid or suspension.

From the inert material, the inert liquid or the suspension exiting raw gas is in the vertically above the container arranged filter chamber in which at least one filter element is arranged out. The clean gas emerging through the at least one filter element is discharged into the environment or circulated during processing.

As a result, a large part of particles of the inert material, the inert liquid or suspension are held back and do not even reach a filter element in which the raw gas to be purified flows through a filter medium and then present as pure gas. In addition, the chemical reactivity of particles can be reduced.

Within the container in the flow direction in front of the connection between the container and the filter chamber, a flow guide element should be arranged, with which a direct flow of raw gas emerging from the inert material, the inert liquid or suspension raw gas can be avoided in the filter chamber.

The vertically upper region of the dip tube as a flow-guiding element can be formed by a conically widening in the direction of the filter chamber design of the dip tube. In addition, the raw gas emerging from the inert material, the inert liquid or suspension can be guided into the filter chamber through a gap, in particular an annular gap, between the vertically upper edge of the flow guide element and the container wall.

Several outlet openings on a tubular conduit or a dip tube can be distributed over the circumference, possibly also arranged in a plurality of rows arranged one above the other, to be available. The outlet openings may also have different free cross-sectional areas, so that raw gas with different flow velocities, directions and beam cross-sectional shapes can escape, which allows influencing the flow of the raw gas within the inert material, the inert liquid or suspension. For example, influence can be exerted on the formation of a fluidized bed with particulate inert material. Namely, it is advantageous to introduce raw gas with a pressure and volume flow into the container and to let emerge from the / the outlet opening (s) of the line or the / the outlet opening (s) of the dip tube, with a fluidized bed formation of the inert material can be achieved.

For safety reasons, it may be advantageous that a shut-off element is arranged between the container and the filter chamber, with which a temporary inflow of raw gas from the container into the filter chamber can be avoided.

An inert material can be selected from mineral flours, in particular quartz sand and salts, and a liquid can be selected from water, glycerol and alkanols, in particular 1,2-propanediol.

A suspension, which is formed with one of the mentioned inert materials and a liquid, in the simplest case water or one of said liquids, may be present in the container to allow raw gas to flow therethrough.

Advantageously, a per se known pressure shock device for cleaning the at least one filter element may be present and while a portion of the filter chamber may be formed conically towards the container. The open in the direction of the container connection area can thus open into the container.

The container or part of the container containing inert material, inert liquid or suspension should be releasably connected to the filter chamber. During use, the container and filter chamber should be so interconnected that leakage of gas from the device and entry of gas from the environment into the device can be avoided.

In the container, a level of inert material, inert liquid or suspension should be met, with which it can be ensured that emerging from the at least one outlet opening of a tubular conduit or a dip tube raw gas flowing through inert material, inert liquid or suspension at any time before it flows into the filter chamber.

The invention will be explained in more detail by way of example in the following.

Showing:

1 a schematic sectional view of an example of a device according to the invention.

At the in 1 As shown, particulate-containing raw gas passes through the tubular duct 1 in a container 2 guided. The container 2 is at rest, ie without incoming raw gas at 30% with quartz sand having an average particle size d ₅₀ of 1.5 mm, as an inert particulate material 3 filled.

In this example, the outlet is 1.1 the tubular conduit 1 inside a dip tube 1.2 arranged so that from the outlet opening 1.1 the tubular conduit emerging raw gas through the dip tube 1.2 towards the bottom of the container 2 flows and through the outlet 1.2.1 of the dip tube 1.2 flows out and through the present as a loose bulk inert material 3 flows through it. The outlet opening 1.2.1 of the dip tube 1.2 is in this example at a distance of a few millimeters to the bottom of the container 2 arranged. It can also be at least one outlet opening in non-illustrated form by the lateral surface of the dip tube 1.2 be present in the form of an opening. One or more such outlet (s) 1.2.1 forming openings may be arranged distributed over the circumference in one or more superposed row (s). Openings can have different sized and differently geometrically shaped free cross sections.

The outlet (s) 1.2.1 However, within a bed, that should be considered loose in the container 2 existing particulate material 3 is formed, an inert liquid or suspension can be arranged.

In a non-illustrated form, in a simple embodiment of a device according to the invention also on the dip tube 1.2 be dispensed with and the raw gas directly from the at least one outlet opening 1.1 the tubular conduit 1 in the inert material 3 , the inert liquid or a suspension to flow.

In the example, the raw gas sucked with a compressor, not shown, with a pressure and volume flow in the loose bed of inert material 3 introduced that with particles above the loose bed inside the container 2 a fluidized bed is formed, from the roughly purified and freed from at least a portion of the pre-contained particles raw gas into a filter chamber 5 flows. In the filter chamber 5 are two filter elements in this example 6 present, through which the pre-purified raw gas flows and can leave the device as clean gas.

To prevent the penetration of particles that have already been separated in advance, particles of the inert material 3 , inert liquid or components of a suspension, the dip tube 1.2 in its vertical upper area, towards the filter chamber 5 has a conical in this direction extension, with a flow guide element 7 for raw gas coming out of the container 2 in the filter chamber 5 flows, is formed.

That from the inert material 3 , Pre-purified crude gas leaving inert liquid or suspension thus does not flow directly into the filter chamber 5 , It passes through an annular gap between the vertical upward facing end face of the dip tube 1.2 and the lid of the container 2 is arranged from the container 2 in the filter chamber 5 , The conical expansion of the flow guide element 7 should be so large that it is at least as large as the free cross section of the inlet port for vorsepariertes raw gas into the filter chamber 5 ,

In one area of the filter chamber 5 , which is designed here as a hollow cylinder, is a shut-off 8th installed, with which a gas-tight separation between container 2 and filter chamber 5 is achievable if, for example, this is required for security reasons.

At the trained as a hollow cylinder region of the filter chamber 5 closes a conical towards filter elements 6 expanding area. This area has an advantageous effect in conjunction with a pressure shock device known per se 9 off, with a cleaning of the filter elements 6 can be achieved. It can by the filter elements 6 falling particles safely into the container 2 fall.

In the example shown, the lid of the container 2 Part of the filter chamber 5 and the vertically upwardly open container 2 can with this part of the filter chamber 5 get connected. For sealing is at least one radially encircling sealing elements 10 available. The container 2 is detachable with the filter chamber 5 connected, which can be achieved with suitable fasteners, such as screws, clamps, springs oam.

Claims (10)

Device for separating exhaust gases containing particles, in which a raw gas containing particles is conveyed by means of a compressor via a tubular conduit ( 1 ) whose at least one outlet opening ( 1.1 ) in a closed container ( 2 ), to which a filter chamber ( 5 ) is connected, wherein in the container ( 2 ) an inert material ( 3 ) in particulate form as a loose bed, an inert liquid or a suspension of an inert material in particulate form and the outlet opening (s) ( 1.1 ) or at least one exit opening ( 1.2.1 ) of a dip tube ( 1.2 ) in which the outlet opening (s) of the tubular conduit ( 1 ) terminate within the inert material, the inert liquid or the suspension, and from the inert material ( 3 ), the inert liquid or the raw gas leaving the suspension in the vertically above the container ( 2 ) arranged filter chamber ( 5 ), in which at least one filter element ( 6 ) is guided, and by the at least one filter element ( 6 ) discharged clean gas into the environment or is recycled during processing. Device according to claim 1, characterized in that inside the container ( 2 ) in the direction of flow before the connection between containers ( 2 ) and the filter chamber ( 5 ) a flow guide element ( 7 ) is arranged, with which a direct inflow of the inert material ( 3 ), the inert liquid or suspension exiting raw gas into the filter chamber ( 5 ) is avoidable. Device according to one of the preceding claims, characterized in that the vertically upper portion of the dip tube ( 1.2 ) as flow-guiding element ( 7 ), through a conical towards filter chamber ( 5 ) expanding formation of the dip tube ( 1.2 ) and that of the inert material ( 3 ), the inert liquid or suspension exiting raw gas through a gap, in particular an annular gap between the vertically upper edge of the flow guide element ( 7 ) and the container wall into the filter chamber ( 5 ) is guided. Device according to one of the preceding claims, characterized in that between containers ( 1 ) and filter chamber ( 5 ) a shut-off element ( 8th ) is arranged. Device according to one of the preceding claims, characterized in that raw gas with a pressure and volume flow into the container ( 1 ) and out of the outlet (s) ( 1.1 ) of the line ( 1 ) or the outlet (s) ( 1.2.1 ) of the dip tube ( 1.2 ) emerges with the fluidized bed formation of the inert material ( 3 ) is reachable. Device according to one of the preceding claims, characterized in that a plurality of outlet openings ( 1.1 ) of a line ( 1 ) or several outlet openings ( 1.2.1 ) of a dip tube ( 1.2 ) should be distributed over the outer circumference and preferably have different free cross sections. Device according to one of the preceding claims, characterized in that an inert material ( 3 ) is selected from mineral flour, in particular quartz sand and salts, and an inert liquid is selected from water, glycerol and polyhydric alkanols, in particular 1,2-propanediol. Device according to one of the preceding claims, characterized in that a pressure-impulse device ( 9 ) for cleaning the at least one filter element ( 6 ) is available. Device according to the preceding claim, characterized in that an area of the filter chamber ( 5 ) conically towards the container ( 1 ) and towards the container ( 1 ) open connection area in the container ( 1 ) opens. Device according to one of the preceding claims, characterized in that the container ( 1 ) or the part of the container ( 1 ), in which inert material ( 3 ), inert liquid or suspension is contained, detachable with the filter chamber ( 5 ) connected is.

Images