DE19546674C1 - Effluent water gas aeration pipe end-fitting incorporates circumferential groove - Google Patents

Abstract

An assembly introduces a gas (especially air) into a liquid (especially effluent water) through a tubular passage and discharges it through a pipe fitting (6) surrounded by a perforated membrane. A gas distribution chamber is positioned between the pipe and membrane. The novelty is that: (a) the gas distribution chamber (8) is ring-shaped around the pipe fitting; (b) the gas distribution chamber is formed by a radial thickening (10) in the fitting end-piece (3), together with a circumferential groove (11); (c) the gas distribution chamber is supported by a circular spring (12) on the fitting end-piece; (d) the gas inlet passage (9) forms an angle of less than 90 deg to the assembly's longitudinal axis, and that the assembly incorporates two opposing gas inlets; (e) the membranes (7) are secured to the end of the fitting by plastic clamps (2,4); (f) the membrane is not perforated in the vicinity of the gas distribution chamber or the entire fitting end-piece.

Description

The invention relates to a gassing device according to the preamble of claim 1.

Such a gassing device is known for example from DE 38 19 305 C2. A longitudinal groove is provided in the support body as a gas distribution space through which the gas can also be brought up to the end of the hose aerator. The membrane is usually not perforated over the longitudinal groove, so that it is in the unloaded condition can perform its function as a backflow preventer and there is a sufficiently large excess pressure in the groove when fumigation is started can form to lift the membrane from the support body.

This hose aerator has the disadvantage that it is often inadequate and in particular uneven fumigation behavior shows what the in Longitudinal unperforated zone of the membrane is still supported.

The object of the invention is therefore to provide a tube aerator with an improved Propose fumigation behavior.

This task is achieved with a hose aerator of the type mentioned solved that the gas distribution space in a ring around the support body is trained.

It has surprisingly been found that a trained such Hose aerator even with the lowest gas throughput Has fumigation behavior. Due to the design of the ring The gas distribution area lifts the membrane at the slightest overpressure evenly from the support body and thus enables optimal fumigation. In No perforated zones are required in the longitudinal direction of the membrane be what further supports the even fumigation behavior.

Further features that advantageously shape the subject of the invention result from the subclaims.

The invention is described below using an exemplary embodiment and Described in more detail with reference to the accompanying drawings.

Show:

Figure 1 shows a hose aerator, partially cut.

Fig. 2 detail A of Figure 1, wherein the gas distribution space is formed by a groove.

Fig. 3 detail A of FIG. 1, wherein the gas distribution space is formed by a spring.

The vacuum valve according to Fig. 1 consists of a supporting body 6 with the head piece 3 and a connecting part 1 for connection to a gas distribution system.

On the supporting body 6 with the head piece 3, a diaphragm 7 is pulled, which is fixed at its two ends by means of clamping rings 2 and 4 and the end piece 5 on the support body. 6

In the head piece 3 of the support body 6 , a gas supply bore 9 is provided at an angle of approximately 60 ° to the longitudinal axis 13 of the hose aerator.

In the area of the gas supply bore 9 , a gas distribution space 8 is formed in a ring around the support body 6 .

The gas distribution chamber 8 is formed by the radial thickening 10 of the head piece 3 of the supporting body 6 and the membrane 7 "about stretched" formed.

The membrane 7 is not perforated in the area of the head piece 3 of the support body 6 .

The operation of this hose aerator can be described as follows:
The gas flows via the connection part 1 and the gas feed bore 9 into the annular gas distribution space 8 , which is closed off by the imperforate part of the membrane 7 .

Even at very low excess pressure, the membrane 7 then lifts off from the support body 6 in a uniform, ring-shaped manner. The gas flows between the support body 6 and the perforated part of the membrane 7 and the tube aerator begins to gas evenly.

Outside the area of the head piece 3 of the support body 6 , the membrane 7 is perforated all around, which further supports the uniform gassing behavior.

The use of the clamping rings 2 and 4 for fastening the membrane 7 has the advantage that, compared to the hose clamps or hose binders conventionally used, there are no protruding parts (screws, closure pieces) to which contamination preferably attaches during operation (so-called braid formation).

In addition, the membrane is damaged during transport protruding and often sharp parts and possible injuries for Assembly personnel prevented.

The use of the clamping rings 2 and 4 also enables simple disassembly and replacement of membranes.

If the clamping rings 2 and 4 , like usually the other parts of the hose aerator, are made of plastic, the hose aerator consists entirely of non-corroding material.

The membrane 7 is assembled using the clamping rings 2 and 4 as follows:

• a) The membrane is pulled over the support body 6 .
• b) The connecting part 1 with the clamping ring 2 is screwed into the head piece 3 of the support body 6 .
• c) The membrane 7 is pinched by the radial thickening 10 of the head piece 3 .
• d) The clamping ring 4 is pushed onto the support body 6 with membrane 7 .
• e) Then the end piece 5 is inserted into the lower end of the support body 6 .
• f) The membrane 7 is pulled with its lower end over the protruding edge of the end piece 5 .
• g) The clamping ring 4 is pushed back down and clamps the membrane 7 .

FIG. 2 shows the detail A from FIG. 1, the gas distribution space 8 being formed by a circumferential groove 11 in the region of the gas feed bore 9 .

FIG. 3 shows the detail A from FIG. 1, the gas distribution space 8 being formed by a circumferential spring 12 on the head piece 3 of the support body 6 .

Claims (11)

1. Gassing device for introducing a gas into a liquid, in particular air in water or waste water, with a tubular support body which has at least one gas supply bore, with a tubular membrane which is at least partially perforated and fastened over the support body and with a gas distribution space between the support body and the membrane in the region of the gas feed bore, characterized in that the gas distribution space ( 8 ) is designed in a ring shape around the support body ( 6 ). 2. Fumigation device according to claim 1, characterized in that the gas distribution space ( 8 ) by a radial thickening ( 10 ) of the head piece ( 3 ) of the support body ( 6 ) is formed. 3. Fumigation device according to claim 1, characterized in that the gas distribution space ( 8 ) is formed by a circumferential groove ( 11 ) in the head piece ( 3 ) of the support body ( 6 ). 4. Fumigation device according to claim 1, characterized in that the gas distribution space ( 8 ) is formed by a circumferential spring ( 12 ) on the head piece ( 3 ) of the support body ( 6 ). 5. gassing device according to at least one of claims 1 to 4, characterized in that the at least one gas supply bore ( 9 ) is arranged at an angle of less than 90 ° to the longitudinal axis of the gassing device. 6. Fumigation device according to at least one of claims 1 to 5, characterized in that two gas feed bores ( 9 ) are provided. 7. gassing device according to claim 6, characterized in that two opposing gas supply bores ( 9 ) are provided. 8. gassing device according to at least one of claims 1 to 7, characterized in that the membrane ( 7 ) is attached at its ends by clamping rings ( 2 , 4 ) on the support body ( 6 ). 9. fumigation device according to claim 8, characterized in that the clamping rings ( 2 , 4 ) consist of plastic. 10. gassing device according to at least one of claims 1 to 9, characterized in that the membrane ( 7 ) in the region of the gas distribution space ( 8 ) is not perforated. 11. gassing device according to at least one of claims 1 to 9, characterized in that the membrane ( 7 ) in the entire region of the head piece ( 3 ) of the support body ( 6 ) is not perforated.