DE10225286A1 - Scoop feed for the biological cleaning stage, at a sewage processing plant, has groups of scoops with constant and adjustable scoops to deliver a set feed volume in a given time span - Google Patents

Abstract

The scoop feed unit (8), for the biological stage of a sewage processing plant, has at least two grouped scoop feeds (9) which are symmetrically offset from each other and tangential at a mounting (18) on a shaft (5). They have separate unchanged scoops (10) and separate adjustable scoops (11).

Description

The invention relates to a feeding device for biological purification stages of Sewage treatment plants, consisting of one mounted on a shaft in the pumping chamber two-stage scoop, which has shut-off devices on the scoop arms, which one Regulation of the amount of waste water.

Such a loading scoop according to the invention is intended to be a controlled transfer of the pumped medium waste water from the pumping chamber into the bioreactor chamber ensure biological purification level of sewage treatment plants.

In the utility model DE 201 09 452 U1 a plant for biological Wastewater treatment proposed in which a two-stage scoop on a shaft in the Pumping chamber installed and driven at the same time with the rotating immersion body becomes. The two-stage scoop has shut-off devices on the scoop arms should serve to regulate the amount of waste water. As from scripture can be seen, the scooping channels are in this construction of a two-stage scoop arranged radially to the drive shaft. This means that wastewater cannot be pumped optimally scooped over the partition between the pumping chamber and the bioreactor chamber be because it is the scoop outlet of the two-stage scoop before reaching the optimal Leaving point. With regard to the constructive design of the described two-stage scoop is an arrangement of the scoops to the scoop at a right angle disadvantageous because this arrangement is only an insufficient filling of the scoops permitted with the pumped medium waste water. An arrangement of two scoops on one Schöpfkanal also has the consequence that in the event of a high level of wastewater, the two scoops conveyed amounts of wastewater in the other scoop channel block so that no regulated scooping process is possible.

Furthermore, the published patent application DE 197 49 699 A1 and Utility model DE 297 19 956 U1 each have a rotary immersion body with scoops for biological Sewage treatment plants described.

Because of the rigid, costly arrangement of the scoops on the Rotary immersion body is a constant and even loading of the rotary immersion body with the Pumped medium wastewater hardly in relation to the actually generated wastewater quantities possible. In times of low wastewater, biology dies for them Pollutant degradation processes in the clarification chambers and on the rotary immersion bodies. Then one required immobilization or formation of a biological lawn in the clarification chambers and on the rotating immersion bodies is usually laboriously done on thin steel cables manually introduced highly porous carrier materials, packed in a stainless steel grid and be mixed with microorganisms.

The invention has for its object a feed scoop of the beginning described further develop in such a way that the loading conveyor downstream immersion bodies in the bioreactor chamber evenly with a actual volume of waste water corresponding to a defined amount of waste water Period of time and, if necessary, for activation or immobilization of the biology and the organic lawn in the biological cleaning stage.

This object is in connection with the preamble of claim 1 solved according to the invention by the characterizing features of claim 1.

The feed scoop according to the invention for biological purification stages exists from at least two group scoop elements, from at least one constant Single scoop element and at least one variable single scoop element, the Group scoop elements tangential to a locking device on a shaft is mounted, are arranged symmetrically offset. At least one variable Single scoop element of the group scoop elements has one on its scoop nose head Immobilization facility on.

An advantageous embodiment of the subject matter of the invention provides that the constant Single scoop elements and the variable single scoop elements in one Group scoop element can be arranged in parallel.

According to the invention it is further proposed that the constant individual scooping elements and the variable individual scoop elements each from a scoop nose, a scoop nose head, one Scoop, a scoop channel and a common scoop outlet in the direction a partition between a pumping chamber and a bioreactor chamber have biological purification level.

It is of particular advantage that the scoops of the constant individual scooping elements and the variable individual scooping elements against the scooping direction an acute angle form in order to optimally fill the scoops with the medium wastewater guarantee.

An expedient embodiment of the subject matter of the invention provides that the Length adjustment of the variable individual scooping elements by means of an adjusting element on Scoop channel is adjustable.

A further development of the subject matter of the invention provides that the variable Individual scoop elements in their scoop nose heads each have a flow control actuator have integrated, through which the regulation of a medium is carried out.

Furthermore, the flow rate control actuator consists of an actuating lever, a Closure element and a scoop drain opening constructed.

Furthermore, it is proposed according to the invention that the immobilization device in Form a lattice box is formed and the inclusion of a porous support material Settlement of microorganisms.

Finally, it is proposed that the feed scoop be made of plastic or metal finished.

Further details of the invention are shown schematically in the drawing with reference to FIG illustrated embodiments described.

Here shows:

Fig. 1 is a side view of the feeder pumping station,

Fig. 2 is a front view of the feeder pumping station,

Fig. 3 shows the section AA of a flow quantity control actuator in the closed position in Fig. 2,

Fig. 4 shows the section AA of a flow quantity control actuator in the open position in Fig. 2,

Fig. 5 shows the section BB of a suction nose and an immobilization device in Fig. 1,

Fig. 6 is a side view of the loading scoop in the assembled state in the biological cleaning stage and

Fig. 7 is a plan view of the loading scoop in the assembled state in the biological cleaning stage.

In FIG. 1, a feed pumping station is shown in the side view. 8 The feed scoop 8 essentially consists of at least two group scoop elements 9 , which are arranged tangentially offset symmetrically on a locking device 18 , which is mounted on a shaft 5 . The group scoop elements each consist of a constant single scoop element 10 and a variable single scoop element 11 , which are arranged in parallel. The constant individual scoop elements 10 and the variable single scoop elements 11 each consist of a scoop nose 12 , a scoop nose head 13 , a scoop throat 14 , a scoop channel 15 and a common scoop outlet 17 . The length adjustment of the variable individual scooping elements 11 is realized by means of an adjusting element 16 on the scooping channel 15 . The Immobilisierungseinrichtungen 23 are mounted on the suction heads 13 and nose is depending in the suction heads 13 a nose Durchflußmengenregulierungsstellglied 20 integrated via the waste water is carried out the regulation of the conveying medium. The flow rate control actuators 20 are composed of an operating lever 21 and a scoop outlet opening 19 in terms of their external operability.

Fig. 2 shows a loading scoop 8 in the front view. The constant individual scooping elements 10 and the variable single scooping elements 11 can be seen , which essentially consist of a scoop nose 12 , a scoop nose head 13 , a scoop throat 14 , a scoop channel 15 and a common scoop outlet 17 . The immobilization devices 23 are attached to the scoop nose heads 13 of the variable individual scoop elements 11 . In each of the scooping channels 15 , a flow rate control actuator 20 is integrated, which in terms of its external operability is composed of one adjusting lever 21 and one scoop outlet opening 19 . The length adjustment of the variable individual scooping elements 11 is realized by means of an adjusting element 16 on the scooping channel 15 .

FIG. 3 shows the section AA of a flow rate control element 20 in the closed position in FIG. 2. The flow rate control element 20 , integrated in the scoop duct 15 , essentially consists of a scoop outlet opening 19 , an adjusting lever 21 and a closure element 22 . The scooping of the pumped medium waste water is not possible in the closed position of the closure element 22 . An outflow of the scooped conveying medium waste water is realized via the opened scoop outlet opening 19 .

FIG. 4 shows the section AA of a flow rate control element 20 in the open position in FIG. 2. The flow rate control element 20 , integrated in the scoop duct 15 , essentially consists of a scoop outlet opening 19 , an adjusting lever 21 and a closure element 22 . The quantity control of the scooped delivery medium is regulated via the position of the closure element 22 in connection with a closure or opening position of the scoop outlet opening 19 . In this position of the flow rate regulating member 20 , a maximum flow rate of the conveying medium waste water can be scooped when the scoop outlet opening 19 is closed.

FIG. 5 shows the section BB of a scoop nose 12 and an immobilization device 23 in FIG. 1. The immobilization device 23 is attached to the scoop nose 12 . It is designed in the form of a lattice box 24 and is used to hold a porous carrier material 25 for the settlement of microorganisms.

FIG. 6 shows a side view of the loading scoop 8 in the assembled state in the biological cleaning stage 1 . It can be seen from this illustration that the charging scoop 8 with the rotating immersion body 6 has a common shaft 5 and thus also a common scoop direction 27 . It is noteworthy in the optimal filling of the feed scoop 8 that the pumped medium draws waste water 26 .

FIG. 7 shows a top view of the loading scoop 8 in the assembled state in the biological cleaning stage 1 . It can be seen from this illustration that the biological cleaning stage 1 essentially consists of a scoop chamber 2 , a partition 3 , a bioreactor chamber 4 , a shaft 5 , a rotary immersion body 6 , a drive motor 7 and a charging scoop 8 . The feed scoop 8 and the rotating immersion body 6 are driven by a drive motor 7 via the common shaft 5 . The scoop outlet 17 of the charging scoop 8 points in the direction of the partition 3 between the scoop chamber 2 and the bioreactor chamber 4 . LIST OF REFERENCES 1 Biological purification stage
2 pumping chamber
3 partition
4 bioreactor chamber
5 wave
6 rotary immersion bodies
7 drive motor
8 loading device
9 group ladder element
10 Constant single scoop element
11 Variable single scoop element
12 scoop
13 scoop nose
14 scoops
15 scoop channel
16 adjustment element
17 scoop outlet
18 locking device
19 scoop drain opening
20 flow regulator
21 control levers
22 closure element
23 Immobilization device
24 lattice box
25 carrier material
26 Waste water pumped medium
27 Scooping direction

Claims (9)

1. loading scoop for biological purification stages of sewage treatment plants, consisting of a two-stage scoop mounted on a shaft in the scoop chamber, which has shut-off devices on the scoop arms, which serve to regulate the amount of waste water obtained, characterized by a) at least two group scoop elements ( 9 ) which consist of at least one constant single scoop element ( 10 ) and at least one variable single scoop element ( 11 ), b) wherein the group scoop elements ( 9 ) tangentially to a locking device ( 18 ), which is mounted on a shaft ( 5 ), are arranged symmetrically offset and c) at least one variable individual scoop element ( 11 ) of the group scoop elements ( 9 ) has an immobilization device ( 23 ) on a scoop nose head ( 13 ). 2. Feeding scoop according to claim 1, characterized in that the constant single scooping elements ( 10 ) and the variable single scooping elements ( 11 ) are arranged in parallel in a group scooping element ( 9 ). 3. feeding scoop according to claim 1 or 2, characterized in that the constant single scooping elements ( 10 ) and the variable single scooping elements ( 11 ) each from a scoop nose ( 12 ), a scoop nose head ( 13 ), a scoop throat ( 14 ), a scoop channel ( 15 ) exist and have a common scoop outlet ( 17 ) in the direction of a partition ( 3 ) between a scoop chamber ( 2 ) and a bioreactor chamber ( 4 ) of the biological purification stage ( 1 ). 4. loading scoop according to one or more of claims 1 to 3, characterized in that the scoops ( 14 ) of the constant individual scooping elements ( 10 ) and the variable single scooping elements ( 11 ) form an acute angle against a scooping direction ( 27 ). 5. Feeding scoop according to one or more of claims 1 to 4, characterized in that the length adjustability of the variable individual scooping elements ( 11 ) is adjusted by means of an adjusting element ( 16 ) on the scooping channel ( 15 ). 6. Feeding scoop according to one or more of claims 1 to 5, characterized in that the variable individual scooping elements ( 11 ) in their scoop nose heads ( 13 ) each have a flow rate control actuator ( 20 ) integrated, via which the regulation of a conveying medium waste water ( 26 ). 7. loading scoop according to one or more of claims 1 to 6, characterized in that the flow rate regulating actuator ( 20 ) from an adjusting lever ( 21 ), a closure element ( 22 ) and a scoop outlet opening ( 19 ) is constructed. 8. Feeding scoop according to one or more of claims 1 to 7, characterized in that the immobilization device ( 23 ) is designed in the form of a mesh box ( 24 ) and serves to accommodate a porous carrier material ( 25 ) for the settlement of microorganisms. 9. feeding device according to one or more of claims 1 to 8, characterized in that the feeding device ( 8 ) is made of plastic or metal.