DE2400075A1 - Large dia. gas washing rotor - with central liq. distributor, and labyrinth gas seal separating dirty and clean gas sides - Google Patents

Abstract

A gas washer comprises a housing, a liq. distributor, and a rotor which constitutes the contact zone between liq. and gas; this rotor is radially outside the liquid distributor, and the gas inlet is radially outside the rotor, so that the gas passes inwards through the rotor and contact zone and leaves through a gase outlet radially inside the contact zone; a labyrinth seal is used between the rotor and fixed housing to prevent any gas from the dirty gas inlet passing into the flow of clean gas; this labyrinth seal consists of a number of rings, each coaxial to the rotor, and mounted alternately on the rotor and housing. Pref. the labyrinth seal is near the outer periphery of the rotor. This arrangement is esp. suitable for rotors exceeding 2 metres. dia.

Description

Gas washer The invention relates to a device in which a gas is in contact is brought with a liquid, hereinafter referred to as a gas scrubber, with a housing in which a liquid distributor for distributing and feeding a Liquid is arranged to a contact zone, which is provided on a rotor and is arranged radially outside of the liquid distributor, with a radially outside the contact zone arranged gas inlet inid a radially inside the contact zone arranged gas outlet.

When operating such rotary type scrubbers, it is important to that it is prevented that unwashed gas goes directly down to the scrubbed gas Can get bypassed the contact zone in which the gas with the scrubbing liquid comes into contact; This is especially important when there is a high percentage of particles (e.g. dust) must be removed from the unwashed gas or when a high mass flow rate is required.

Most scrubbers so far have been with a liquid seal provided between the rotor and the stationary housing, the washing liquid has often been used as the liquid of the liquid seal. Since the Ze; r # trifugal forces (of the order of 15 to 50 g), caused by the rotary motion of the rotor sev-zeuat will also act on the liquid, a small amount of liquid is sufficient, to achieve a seal here. Such liquid seals were used with good results on rotary type scrubbers where the inner rotor has a diameter between one and two meters. For the Nowadays, however, ever increasing amounts of industrial gases are being used much larger scrubbers are required.

It has been shown that with larger gas scrubbers a liquid seal is unsatisfactory because of the high peripheral speeds that are required, about the centrifugal forces to generate that for scrubbing the gas required are.

In addition, there is the risk that due to the vibrations, which result from the rotary movement and due to structural inaccuracies that Liquid is pumped out of the liquid seal. The invention is the task underlying to create a gas scrubber of the type in question the sealing difficulties mentioned above are avoided, so that the creating gas scrubbers, for example, compared to those with liquid seals provided gas scrubbers, can be carried out with a larger scope.

In the case of a gas scrubber of the type mentioned at the outset, this is the task according to the invention achieved in that a labyrinth seal between the rotor and the housing is provided through which the gas inlet is separated from the gas outlet and which consists of a plurality of concentric, mutually spaced, is formed coaxially to the rotor extending rings, with one other adjacent rings are alternately attached to the rotor and the housing. That dry labyriiith seals to be applicable to gas scrubbers has not been considered possible so far because Labyrinth seals only act sufficiently sealing when the interacting parts the seal are precisely manufactured with narrow tolerance limits. With the large dimensions, As it is the case for the seal in gas scrubbers, it is practically not possible to adhere to the required tight tolerance limits in terms of production technology. Surprised however, it has now been found that it is possible to use labyrinth seals in gas scrubbers to apply with coarser tolerances. It has been shown that that in the case of gas scrubbers of the rotary type, the labyrinth seal is arranged at such a point and designed in such a way that when the rotor rotates due to the sish here resulting circulation speed of the gas a pressure difference at the labyrinth seal occurs, which prevents the pressurized, unwashed gas bypassing the contact zone or cleaning zone through the labyrinth seal can flow through into the area of the scrubbed gas.

In a preferred embodiment of the invention, they are Sealing elements of the labyrinth seal forming rings in the vicinity of the outer circumference of the rotor arranged. Here, the required pressure difference can be applied to oer The labyrinth seal is particularly easy to produce, since the gas with considerable Circumferential speed in operation.

Due to the fact that the gas in the area of the labyrinth seal has a rotational speed which is between the peripheral speed of the rotor and the speed is slull, particularly good results are achieved if according to a further embodiment of the invention concentric to the rings blades are provided on the rotor close to the L.shyrinth seal, which are shaped so that the passage of unwashed gas through the labyrinth seal counteracting pressure is generated.

Alternatively or in addition, blades can also be attached to the stationary Part of the labyrinth seal, i.e. on the housing of the gas incinerator.

The blades can be located radially outside next to the rings of the labyrinth seal of the rotor or the housing and one of the labyrinth seal facing away Generate gas flow or the blades can be radial be arranged inside next to the rings on the rotor and / or on the housing and a generate gas flow directed towards the labyrinth seal.

It could also be both radially inward and radially outward horizontal blades are provided, so that a pump or a fan is very high Effectiveness is formed.

This not only allows unwashed gas to flow through the labyrinth seal can be prevented through, even if this with very coarse Tolerances, but it can, if desired, also be achieved that a small amount of scrubbed gas through the labyrinth seal Side of the unwashed gas flows. This may be desirable in many cases, because it is particularly effective in preventing unswashed gas from being bypassed the contact zone can come into direct contact with the scrubbed gas.

The invention is illustrated below with reference to one in the drawing illustrated embodiment explained in detail.

The figures show: FIG. 1 a schematized and partly ab1. # Smelt drawn Cross section through a gas scrubber according to an embodiment of the invention; FIG. 2 shows an enlarged detail from FIG. 1 and FIG. 3 shows a broken off Drawn section along the line 3-3 of FIG.

The rotary-type gas lashing device shown in FIG. 1 has a housing 10, in which a rotor 12 is arranged, which has an annular liquid distributor 14 and Rontaktpiatten 16 carries, which radially within an annular contact zone are arranged outside the liquid distributor 14. The contact plates 16 are arranged in planes which run essentially parallel to the rotor axis 18 and form passages for a countercurrent gas flow which pass through the housing 10 an inlet 20 and for a flow of liquid coming from the liquid manifold 14 from radially outwards under the influence of centrifugal force st.rfimt. The washed Gas flows out in the general direction indicated by an arrow X. Of the Inlet 20 is arranged so that the gas is supplied tangentially. The one in the The gas scrubbers shown in the drawing are both the liquid distributor as the contact plates 16 are also provided on the same rotor. In many cases they are however, separate rotors are provided for the contact plates and the liquid distributor. The rotor carrying the contact slats rotates around the same axis as that of the liquid distributor, however, is arranged to run freely. Will the The rotor of the liquid distributor is driven, then the liquid distributor acts on it dispensed liquid touches the contact plates and sets their rotor in rotation, however with reduced speed.

To prevent unwashed gas directly into the stream of the washed Gas enters by bypassing the contact zone, is a labyrinth seal 22 provided between deir, housing 10 and rotor 12.

The labyrinth seal 22 is of the usual structure, but the Sealing elements compared to normal labyrinth seals have a larger mutual Distance. As shown in Fig. 2, five rings 2d, 26, 28, 30 and 32 are provided, which are arranged concentrically to the axis of the rotor 12 are. The rings 24, .28 and 32 are on the stationary housing 10 and between these arranged rings 26 and 30 are attached to the rotor 12 The height of each ring is less than the distance between the housing 10 and the rotor 12 corresponds, so that the gas flowing through the labyrinth duct 22 is essentially a has to cover sinusoidal path.

Two blade rings 36 and 38 are angrlzrac'ilt on the rotor 12, wherein a vane ring radially inside the innermost ring of the labyrinth seal and the other vane ring radially outside of the outermost ring of the labyrinth seal arranged is. There is a relative movement between the top of the rotor 12 and that located between the housing 10 and the top of the rotor 12 If there is gas, the blade ring 36 and the blade ring 38 act as a pump or fan, around the radially inward flow of gas through the labyrinth seal to counteract.

As an alternative or in addition, a blade ring could be attached to one or more of several of the rings 24, 26, 28, 30, 32 directly in the sinusoidal flow path, 'through the labyrinth seal iiindurch leads, be arranged because in these sen interiors the gas has a certain flow velocity relative to each of the surrounding walls having.

When one realizes that it is desirable to have a back pressure or a gentle flow of gas from the side of the scrubbed gas to the side to maintain the unleashed gas through the labyrinth seal, it can be seen that blades could be arranged on the inye 26 and 30, namely in the vicinity of the space between the rings 24, 26 and the intermediate space between the rings 28 and 30 to allow a gas flow against the side of the unwashed To cause gas alone. Narrow nonylen, the rotation was clockwise and there would be blades on rings 26 and 30 as shown in Fig. 3 at 40, shaped, then these would be arranged on the rings 26 and 30 so that the convex Side is directed upwards towards the opening between the rings 24 and 26.

In any case, the blades are arranged so that they one against the Side of the unwashed gas directed gas pressure into the labyrinth seal In Fig. 3 the blades are which as shown at 40 is shaped, arranged as it is rectangular for clockwise rotation is and therefore act, as can be seen, on the gas in such a way that a flow component is generated by the radially inner blades against the. Labyrinth seal runs radially outwards and an overpressure on the inside of the labyrinth seal generated.

If between the clean gas chamber and the chamber with the There is only a slight pressure difference in the inlet for the unwashed gas the size of the labyrinth seal by suitable attachment and shaping The overpressure generated by blades has to be very low and only needs a few Centimeters: 1 water column to achieve the desired effect.

Claims (6)

P a t e n t a n s p r ü c h e 1. Gas scrubber with a housing in which a liquid distributor arranged for distributing and supplying a liquid to a contact zone is provided on a rotor and radially outside of the liquid distributor is arranged, with a gas inlet arranged radially outside the contact zone and a gas outlet arranged radially within the contact zone, characterized in that that a labyrinth seal (22) is provided between the rotor (12) and the housing (10) by which the gas inlet (20j is separated from the gas outlet and which are made up of a plurality concentric, spaced apart, coaxially to the rotor (12) Rings (24, 26, 28, 30, 32) is formed, with adjacent rings alternating are attached to the rotor (12) and to the housing (10). 2. Gas scrubber according to claim 1, characterized et in that the rings (24, 26, 28, 30, 32) arranged in the vicinity of the outer periphery of the rotor (12) are. 3. Gas scrubber according to claim 2, characterized in that concentrically to the rings (24, 26, 28, 30, 32) on the rotor (12) near the labyrinth seal (22) arranged blades (36, 38, 40) are provided which are shaped so that one counteracting the flow of unwashed gas through the labyrinth seal (22) Pressure is generated. 4. Gas scrubber according to claim 3, characterized in that the blades (38) arranged radially outside next to the rings (24, 26, 28, 30, 32) of the rotor (12) are and generate a gas flow directed away from the labyrinth seal (22). 5, gas scrubber according to claim 3, characterized in that the blades (36) arranged radially inward next to the rings (24, 26, 28, 30, 32) of the rotor (12) and generate a gas flow directed towards the labyrinth seal (22). 6. Gas scrubber according to claim 3, characterized in that both radially inside as well as radially outside next to the rings (24, 26, 28, 30, 32) of the rotor (12) arranged blades (36, 38, 40) are provided, of which the radially inward located blades directed against the labyrinth seal (22) and the blades located radially åuSerll21h are directed away from the labyrinth seal (22) Generate gas flow. Blank page