DE4021094A1 - Sepn. of dust from air current - involves chamber and fan suction sides are connected to two outlet pipes - Google Patents

Abstract

The air-current chamber for dust-extraction has an oblong housing (2) with a first outlet pipe (6) inside one end, and whose axis is parallel to that of the housing. This pipe is clear of the housing, and it contains a second outlet pipe (7) parallel to and clear of it. A first radial, axial or tangential feed pipe (9) delivers into an annular chamber (8) round the first outlet pipe, and open to the other end of the housing. Swirl is generated by guide vanes (10) in the annular chamber, or by mounting the feed pipe tangentially. A second feed pipe (11) delivers into the other end of the housing, being either tangential or equipped with vanes (14) to generate swirl. A fan (15) is connected on the suction side to an outlet pipe, while a secondary fan (16) is connected at the pressure side to a feed pipe. The first fan is connected at the suction side to the second outlet pipe. The second is connected at the pressure side to the second feed pipe and at the suction side to the first outlet pipe. USE/ADVANTAGE - Less power is required by second fan in dust extraction system.

Description

The invention relates to a flow chamber according to the Oberbe handle of claims 1 or 2.

Such a flow chamber is already common. she is as Dust collector trained, and the induced draft fan is compatible with the Suction side connected to the second outlet pipe. The second The suction fan is on the first outlet pipe with its suction side and connected with its pressure side to the first feed pipe.

The invention has for its object this flow to further develop the chamber and to educate a low achievement len that the secondary fan has to apply.

To solve this problem, a flow chamber has a gangs mentioned type according to the invention the characteristics of the kenn drawing part of claim 1 or patent Proverbs 2.

The one fed from the secondary blower into the second feed pipe The elongated tubular casing of the stream needs air  chamber only once from one end to the other end of the Flow chamber to flow through, so that the pressure loss in the flow chamber that the secondary blower has to overcome, is low. Because of the resulting low performance the secondary fan can be made geometrically smaller and can also be used without any problems if the by this secondary fan is withdrawn from the flow chamber and high air returned to the flow chamber Temperature. This has to go through the first feed pipe sucked raw gas the housing of the flow chamber twice through flow so that the pressure to be overcome for this raw gas loss is correspondingly high. This pressure loss must be applied by the induced draft fan, this can accordingly be geometrically large, because that is from him clean gas extracted from the flow chamber if necessary can be easily cooled before the suction blower happens.

Furthermore, a high degree of dust separation for the by first feed pipe raw gas entering the flow chamber achieved because this raw gas on its way to second outlet pipe passes the flow chamber twice.

By the measure according to claim 3, the Se performance to be applied even further reduced will.

The curdling and its advantages are based on the drawing two exemplary embodiments explained in more detail:

Fig. 1 and Fig. 2 show a highly schematic longitudinal section of a flow chamber according to the invention.

This flow chamber has an elongated tubular housing ( 2 ) which is up with a vertical longitudinal axis ( 3 ). This housing ( 2 ) tapers at the lower end with the formation of a cone ( 4 ) up to a dust discharge ( 5 ).

At the upper end of the housing is located within the Gehäu ses (2) a first outlet tube (6) coaxially to the housing Ge (2) is arranged. Within this first outlet tube (6) is arranged coaxially with the first outlet tube (6) and the housing (2) with distance from the first outlet tube (6), a second outlet pipe (7).

The first outlet pipe ( 6 ) is at a distance from the tubular housing Ge ( 2 ) and forms an annular chamber ( 8 ) in the intermediate space, which is open to the lower end of the housing and closed to the upper end of the housing. A first feed pipe ( 9 ) opens into this annular chamber ( 8 ) radially, tangentially or axially. Furthermore, be found in this annular chamber ( 8 ) at the bottom towards the lower end of the opening fixed guide vanes ( 10 ) for stimulating a swirl flow on the inside of the housing ( 2 ). These guide vanes ( 10 ) can be omitted if the first feed pipe ( 9 ) opens tangentially into the annular chamber ( 8 ).

At the lower end of the housing there is a second feed pipe ( 11 ) which is arranged coaxially to the housing ( 2 ), the opening of which is directed towards the upper end of the housing and opens in the axial direction into the housing ( 2 ) and the distance from the housing ( 2 ) Has. In the space formed by this distance between the second feed pipe ( 11 ) and the Ge housing ( 2 ) on the outside of this second feed pipe ( 11 ), a flat, annular diaphragm ( 12 ) is attached, which with the inside of the housing ( 2 ) an annular dust discharge slot ( 13 ) in the cone ( 4 ).

Guide vanes ( 14 ) are arranged inside the mouth opening of the second feed pipe ( 11 ) for stimulating a swirl flow about the longitudinal axis ( 3 ) of the housing ( 2 ).

In the flow chamber of Fig. 1, an induced draft fan (15) is joined with its suction side to the second outlet pipe (7) attached. A secondary fan ( 16 ) is connected with its Drucksei te on the second feed pipe ( 11 ) and with its suction side on the first outlet pipe ( 6 ).

In contrast, in the flow chamber according to FIG. 2, the suction draft fan ( 15 ) is connected with its suction side to the first outlet pipe ( 6 ). The secondary fan ( 16 ) is connected with its suction side to the second outlet pipe ( 7 ) and with its pressure side to the second feed pipe ( 11 ).

The induced draft fan ( 15 ) sucks dust-laden raw gas through the first feed pipe ( 9 ), which emerges with a swirl from the intermediate chamber ( 8 ) and flows in the form of a helical flow ( 17 ) on the inside of the housing ( 2 ) to the lower end of the housing . The orifice ( 12 ) reverses the axial component of the helical flow ( 17 ) while maintaining the swirl, so that the raw gas now flows in the form of a helical flow ( 18 ) near the longitudinal axis ( 3 ) from the lower end of the housing to the upper end of the housing.

The secondary air ( 19 ) conveyed by the secondary blower ( 16 ) through the second feed pipe ( 11 ) into the housing ( 2 ), provided with a swirl by the blades ( 14 ), cleans the raw gas in the flow ( 18 ).

While the induced draft fan ( 15 ) draws clean gas from the housing ( 2 ), the dust separated from the raw gas passes through the discharge slot ( 13 ) into the cone ( 4 ) and can be discharged from the dust discharge ( 5 ).

Claims (3)

1. flow chamber with an elongated tubular housing ( 2 ) and a at one housing end within this housing ( 2 ) formed first outlet pipe ( 6 ) with the longitudinal direction of the housing ( 2 ) parallel tube axis, the distance from the housing ( 2 ) and in which a (7) is formed with distance from the first outlet tube (6) occurs for the first tube outlet tube (6) parallel second stop,
with a first radial, axial or tangential To tube ( 9 ), which opens into an annular chamber ( 8 ) located between the housing ( 2 ) and the first outlet tube ( 6 ), to the other end of the housing, and which is used to excite a swirl flow in Housing ( 2 ) opens tangentially into the annular chamber ( 8 ) and / or a guide vane ( 10 ) in the annular chamber ( 8 ) is assigned to excite the swirl flow,
with a second feed pipe ( 11 ) at the other housing end, which opens tangentially into the housing ( 2 ) to excite a swirl flow and / or to which a guide vane ( 14 ) is assigned to excite this swirl flow,
with a suction fan ( 15 ) whose suction side is connected to an outlet pipe, and
with a secondary blower ( 16 ), the pressure side of which is connected to a feed pipe,
characterized,
that the suction fan ( 15 ) with its suction side on the two th outlet pipe ( 7 ) and the secondary fan ( 16 ) with its pressure side on the second feed pipe ( 11 ) and with its suction side on the first outlet pipe ( 6 ) is connected. 2. flow chamber having an elongated tubular housing (2) and a within the formed first outlet pipe (6) axis to a housing end of the housing (2) with parallel to the longitudinal direction of the housing (2) pipe, which distance from the housing (2) has and in which there is the first outlet tube (6) parallel second off occurs tube (7) at a distance from the first outlet tube (6) is formed,
with a first radial, axial or tangential To guide tube ( 9 ), which opens into an annular chamber ( 8 ) located between the housing ( 2 ) and the first outlet tube ( 6 ), to the other end of the housing, and that for stimulating a swirl flow in Housing ( 2 ) is tangential to the housing wall and / or a guide vane ( 10 ) in the annular chamber ( 8 ) is assigned to excite the swirl flow,
with a second feed pipe ( 11 ) at the other end of the housing, which opens tangentially into the housing ( 2 ) to excite a swirl flow and / or to which a guide vane ( 14 ) is assigned to excite this swirl flow,
with a induced draft fan ( 15 ), the suction side of which is connected to an outlet pipe, and
with a secondary blower ( 16 ), the pressure side of which is connected to a feed pipe,
characterized,
that the suction fan ( 15 ) with its suction side on it most outlet pipe ( 6 ) and the secondary fan ( 16 ) with its pressure side on the second feed pipe ( 11 ) and with its suction side on the second outlet pipe ( 7 ) is connected. 3. Flow chamber according to claim 1 or 2, characterized in that the second feed tube ( 11 ) with the longitudinal direction of the housing ( 2 ) parallel tube axis is formed within the housing ( 2 ), has a distance from the housing ( 2 ) and in its mouth the guide vane ( 14 ) to stimulate the swirl flow.