DE20020643U1 - Device for separating solids from diesel exhaust gases - Google Patents

Description

- 1 DESCRIPTION

DEVICE FOR SEPARATION OF SOLIDS FROM HOT EXHAUST GASES, PARTICULARLY FOR CLEANING DIESEL EXHAUST GASES

TECHNICAL AREA

Today, drive technology uses a large number of diesel engines in construction machinery, trucks, cars and stationary combined heat and power plants. These leave behind a residue known as diesel exhaust, which is produced in considerable quantities. Exhaust gas purification in the area of dust and particle separation has been neglected to date. The consequential damage is now known and must be remedied immediately or at least reduced, but the known state of the art technology was only in limited demand and was hardly used; perhaps it was too large, complicated and too expensive.

STATE OF THE ART

Such devices are known from DE-OS 31 22 026 and DE 38 16 727. The US Army in Ramstein has been using a flue gas scrubber from me in tank engine maintenance since 1994 and is very satisfied. The PLK-Weinsberg State Hospital operates an emergency generator with 600 KW every day from 7 a.m. to 12 p.m. to wash and dry the bed linen of those in need of care. The odor nuisance and soot discharge were the reasons for purchasing the systems in both systems; today none of the employees there would want to do without retrofitted exhaust gas purification.

DESCRIPTION OF THE INVENTION

The invention relates to a gas scrubber, in particular for flue gas streams from diesel engines, with a treatment chamber through which gas flows and a spray head arranged therein as a spray device rotating about an approximately horizontal central axis, which can be supplied with a washing liquid to be sprayed, preferably via a shaft carrying the spray head, to form a liquid coating which adheres to the members and is projected outwards from the member arrangement under the influence of centrifugal forces in the form of an annular spray zone. The particular advantage of this arrangement is that spray nozzles are no longer required, which are otherwise always at risk of clogging.

Rather, the washing liquid to be sprayed is torn and swirled by the comparatively fast rotating elements at such a speed that very small liquid droplets are formed.

Due to new findings and further development handling, the flue gas scrubbing is explained and described in detail below.

1. By arranging two or more cross-sectionally enlarged link rings that are spaced apart on the hub. These cross-sectionally enlarged link rings arranged at a distance increase the area of spray of the washing liquid and significantly improve its stabilization in the area of effect.

2. The intake pipe in the center of the washing chamber with the cross-sectional extensions reduces the flow velocity of the raw gases and increases the intake cross-section, stabilizes the gas intake and increases the residence time of the raw gases in the spray area, which leads to a large-area liquid wetting.

3. The device is now simplified by the aforementioned measures and is operated without the usual downstream induced draft fan,

4. This device with its vertical orientation and small design is the ideal solution that can be easily used in many variations in new systems and retrofits.

5. The drive motor with the spray head is continuously controlled and operated with a frequency converter and adapts to the respective requirements of the overall system.

The features mentioned above will significantly simplify and reduce the cost of gas scrubbing in the future.

The basic washing liquid consists of calcium compounds, preferably caustic soda. The cleaning effect is based on the fact that soot, dust, acidic pollutants such as sulphur dioxide, sulphurous acids and hydrochloric acid form harmless, poorly soluble compounds with the calcium compounds and can be easily filtered out of the gases using the washing liquid.

For use in diesel exhaust gas purification and its desired effect, bio-oil must be added to the washing water; a washing water temperature of 50° to 70° C enables good mixing of water and oil. The water-oil mixture, which is sprayed in large quantities, represents intensive surface contact between the dust particles, the wet calcium compounds and the acidic pollutants, which in turn is promoted by good mixing of the wet calcium compounds with the gas and a long residence time of the gas thus mixed in the gas scrubber.

The separation of pollutants from the washing water can be carried out in several variants; the state of the art is diverse and therefore not described in detail.

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Therefore, the object of the invention is to create a gas cleaner which, with very little construction effort, is characterized by good spraying of the washing liquid and thus a particularly high cleaning efficiency and can be retrofitted to old and new systems with little effort.

The diesel exhaust gas temperatures are between 350° - 550° C. By installing a heat exchanger upstream, the exhaust gas heat of up to 200° C can be used cost-effectively. This is state of the art. The hot diesel exhaust gas is sucked into the device with the washing chamber, on the front wall of which a spray head is placed and on the downstream side is partly bordered by the baffle plate, the slotted baffle ring, the stepped, expanded intake pipe in the axle area and ends at a distance in front of the spray head in the spray area. The aeromechanically generated washing water curtain, with the rotating fine oil-adhering washing water droplets, which form a large surface area, wets and settles the dust particles. The rotating gas-filled washing water curtain on the housing wall area flows spirally towards the annular space due to gravity. The rotating water curtain, which ends in a flowing water— Mass passes over, covers the entire housing wall area all around and flows with the released gas bubbles as clean gas through the annular space into the turning chamber, the retaining ring separates and directs a partial flow of the gas-water mixture in a spiral to the intake pipe rotating back into the spray area and thus passes endlessly through the spray area. The rotating flow around the axis, the translational flow along the housing wall and the rotating return flow in the axis area to the spray head, which is generated aeromechanically with the spray head, is a three-dimensional flow that is being used for the first time in water spraying.

The three-dimensional gas flow during biomass combustion is described in the utility model DE 200 01 926 U 1.

The rotating gas-water mixture generated by the spray head is so stable in the spray area that a constant negative pressure acts on the extended intake pipe and in the peripheral area, the housing wall in front of the annular space, a stable overpressure is present all around, so that an additional induced draft fan for gas transport is no longer necessary.

The casing wall constriction, which begins after the annular space, directs the rotating incoming wash water mass to the axle area and stops its rotation.

The washing water flows into the washing water basin via the washing water return pipe, the water-saturated clean gas, relaxed and considerably reduced in volume, flows out into the atmosphere at a temperature of approx. 50° - 60°C via the clean gas outlet.

- 4 SHORT
DESCRIPTION BY DRAWINGS

The invention is illustrated in the following with reference numbers using an embodiment shown in the drawing, in which:

Fig. 1 is a section through the device according to the invention, Fig. 2 is a cross-section along the line A-A of Fig. 1.

WAYS TO CARRY OUT THE INVENTION

A gas washing battery 20 is used to clean hot diesel exhaust gases.

A gas washing battery 20 is a compact structural unit. The gas washing battery 20 has an outer housing wall 28, which is circularly cylindrical in its circumference and encloses the spray head 33, the washing chamber 21, the baffle plate 38, the turning chamber 22 and an intake pipe 25 with extensions 26 and 27 and the axis area 30 in a cylindrical manner. On the side facing away from the turning chamber 22, the housing wall 28 is closed by a front wall 72. In the front wall 72 there is a central opening in which a shaft 32 is rotatably mounted, which can be set in rotation about the longitudinal axis 30 of the gas washing battery 20 via a motor drive 31. In the present case, the shaft 32 has a spray head 33 which has chain links 52 consisting of the link elements 56 and 57, which are arranged in stages as link rings 53, 54, 55 which rotate together with the shaft 32 about the axis 30.

The spray head is placed in the washing chamber 21 on the front wall 72, the free space of the washing chamber 21 around the spray head 33 up to the intake pipe 25 is referred to as the spray area 35. On the downstream side, the washing chamber 21 is delimited by the baffle plate 38, equipped with a baffle ring 41 with slots 42, the cross-sectional extensions (26, 27), the intake pipe 25 in the axial area 30, which penetrates the baffle plate 38, the washing chamber 21 is directly connected to the turning chamber 22 on the gas side via the annular space 40, the washing water return pipes are designated 51, the clean gas outlet 50.

Fig. 2 shows a cross section of the line A-A, in which the extensions 26 and 27 of the intake pipe 25, the baffle plate 38 and the annular space 40 with the housing wall 28 are shown.

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The device is operated as follows.

The spray head 33 is driven in rotation, at the same time the washing liquid pump (not shown) starts. Washing liquid flows into the cavity of the spray head 33 via the washing water supply line 45, and the link rings 53, 54, 55 are supplied with washing liquid via the openings 47 and the annular gap 46.

The rotating wash water curtain generated is compact up to the intake pipe 25 and thus forms the spray area 35. The water curtain, consisting of wash water droplets which are loaded with the sucked-in raw gas, mix and are thrown towards the housing wall 28 due to gravity, generates a stable constant negative pressure in the axis area 30, which sucks the flue gases to the spray area 35, diverts them and allows them to rotate up to the baffle plate 38.

The generated three-dimensional gas-water mixture flow leads to the separation of clean gas and wash water in the wash chamber 21 in front of the baffle plate 38.

A partial flow of the moist rotating clean gas flows under pressure via the annular space 40 to the turning chamber 22, is expanded and flows out via the clean gas outlet 50.

The remaining partial flow in front of the baffle plate 38 is sucked in a rotating manner around the intake pipe 25 to the spray area 35 and passes through the continuous washing process in a stabilizing manner. The rotating washing water flows via the annular space 40 on the housing wall area 28 into the turning chamber 22 via the washing water return pipe 51 into the washing water basin, which is not shown.

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REFERENCE NUMBERS FOR THE "GAS WASHING BATTERIES" UTILITY MODEL APPLICATION

20 Gas washing battery 21 Washroom 22 Turning chamber 23 Constriction 24 25 Intake pipe 26 1. 0 extension 27 2. 0 extension 28 Housing wall 29 30 axis 31 Drive motor 32 Wave 33 spray nozzle 34 35 Spray area 36 38 Baffle plate 39 40 Annular space 41 Damping ring 42 Slots 43 44 45 Wash water supply 46 Annular gap 47 Openings- spray head 48 hub 49 50 Clean gas outlet 51 Wash water return pipes 52 Chain links 53 1. Linked wreath 54 2. Linked wreath 55 3. Linked wreath 56 Link elements 57 Link elements 58 59 60

70 Arrows Gas Flow 71

72 Front wall

73 Rear wall 74

75 Housing wall area

76

77

78

79

80

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Claims (5)

1. Device ( 20 ) for separating soot particles from hot diesel exhaust gas streams by spraying washing liquid, with - a spray head ( 33 ) for generating a rotating gas-water mixture in the washing chamber ( 21 ), - an intake pipe ( 25 ) which penetrates the rear wall ( 73 ) and the baffle plate ( 38 ) in the axial area ( 30 ) and ends with an enlarged cross-section at a distance in front of the spray head ( 33 ) in the spray area ( 35 ), - a baffle plate ( 38 ) delimiting the spray head ( 33 ) on the downstream side, at least partially isolating the spray head ( 33 ) from the downstream turning chamber ( 22 ), - an annular space ( 40 ) radially surrounding the baffle plate ( 38 ) and a housing wall ( 28 ) surrounding the annular space ( 40 ), characterized in that
in the washing chamber ( 21 ) there is a spray head ( 33 ) with two or more cross-sectionally enlarged link rings ( 53 , 54 , 55 ) which are arranged at a distance on the hub ( 48 ),
that an intake pipe ( 25 ) with cross-sectional extensions ( 26 , 27 ) penetrates the rear wall ( 73 ), the turning chamber ( 22 ), the baffle plate ( 38 ) in the axial area ( 30 ) and ends with an expanded cross section in front of the spray head ( 33 ) at a distance in the spray area ( 35 ),
that there is an annular space ( 40 ) between the baffle plate ( 38 ) and the housing wall ( 28 ), with which the washing chamber ( 21 ) and the turning chamber ( 22 ) are connected in terms of flow, that the washing chamber ( 21 ) is largely delimited by the intake pipe ( 25 ) and the baffle plate ( 38 ) to the turning chamber ( 22 ) and the turning chamber ( 22 ) is arranged downstream of the washing chamber ( 21 ). 2. Device according to claim 1, characterized in that the housing wall ( 28 ) as a structural component tapered in cross section by the constriction ( 23 ) ends flush with the rear wall ( 73 ). 3. Device according to claim 1, characterized in that the turning chamber ( 22 ) has washing water return pipes ( 51 ) downwards and a clean gas outlet ( 50 ) upwards. 4. Device according to claim 1, characterized in that the baffle plate ( 38 ) is designed as a baffle ring ( 41 ) on the upstream side in the peripheral region and additionally has slots ( 42 ) all around. 5. Device according to claim 1, characterized in that the washing water supply line ( 45 ) ends axially with an annular gap ( 46 ) in front of the hollow spray head.