DE29620825U1 - Device for separating and cleaning a mixture of suspended matter, sediment and waste water - Google Patents

Description

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29 November 1996 *"l,**» .! ·· j"*;;*'

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DESCRIPTION

Device for separating and cleaning a floating,

Sediment-wastewater mixture 05

TECHNICAL AREA

The present invention relates to a device for separating and cleaning a suspended matter, sediment-wastewater mixture, in particular a sand-water-organic mixture, with a storage container to which the mixture is fed via an inlet and conveying water is drawn off via an outlet, a device for generating a flow that acts on the mixture, and a discharge device for discharging the separated and cleaned sediment mixture.

In new regulations for the treatment of municipal waste, the provisions to be complied with have been drastically tightened. This applies in particular to the landfillability and recyclability of sand from sand traps in municipal sewage treatment plants. As part of the treatment of wastewater in sewage treatment plants, sand traps are used in one of many purification stages in which heavy sediment (sand) is separated from the wastewater. The aim is to wash out the organic part that has been retained in the sand trap to such an extent that the requirements for sand to be landfilled can be met or the conditions for the sand to be recyclable can be implemented.

STATE OF THE ART

In known devices for cleaning and separating sand from a sand-wastewater mixture, a relatively high percentage of organic material remains attached to the

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sand removed. Such sand does not usually meet the limit values for loss on ignition specified in the newer technical instructions for the treatment of municipal waste. It is required that the loss of substance during an igniting process over a defined period of time and at a defined temperature must be less than 3% of the initial mass.

A device for cleaning and separating sand is known in which the system is fed with the sand/water-organic mixture via an inlet line with a swirl chamber to a so-called Coanda tulip. The Coanda effect creates a defined flow in the inlet area. Due to the density differences, the sediment is directed into the sedimentation zone, while the specifically lighter parts are kept in suspension and carried away. The sedimented substances settle on a perforated intermediate floor. Process water is introduced using the flushing system underneath. An agitator is used to support the separation between organic and mineral components.

DESCRIPTION OF THE INVENTION

The present invention is based on the task or technical problem of specifying, based on the cited prior art, an improved device for cleaning and separating a wastewater mixture, which ensures reliable separation, enables a high degree of cleaning and, with regard to the separated material, complies with the requirement for landfilling or creates the prerequisite for recyclability.

The device according to the invention for separating and cleaning a mixture of suspended matter, sediment and waste water is characterized by the

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Features of independent claim 1 are given. Advantageous embodiments and further developments are the subject of the dependent claims.

Accordingly, a device for separating and cleaning of the type mentioned at the beginning is characterized in that there is a separate washing zone to which the mixture or the sediment mixture that has sunk within the storage container is fed laterally via a feed, a collection unit, in particular sand stock, and the discharge unit are arranged below the washing zone, the device for generating a flow is arranged above the discharge unit and below the lateral feed, the device being operated using the current pulse method, and a vibrator unit is present within the washing zone to homogenize the sediment mixture that accumulates within the washing zone.

By deliberately generating an upflow pulse flow in a separate sediment collection unit in conjunction with the use of a vibrator unit, an optimal degree of cleaning of the sediment, especially sand, can be achieved. As a result of the internal friction in conjunction with the vibration and the flow, even the finest organic sludge components are washed out. The vibrator unit also prevents cavities from forming in the sediment mixture or sand due to bridging, so that a very good homogenization of the sedimented sand can be achieved, whereby a very high degree of cleaning can be achieved through the parallel upflow pulse process.

However, the device according to the invention is not only limited to the cleaning of sediment from a sand trap. Any sewer flushing material or granulate, in particular plastic, metal, broken glass, for example ampoules, which are filled with

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Drugs or the like can be reliably separated and cleaned using the device according to the invention.

A particularly preferred embodiment of the device according to the invention is characterized in that in the bottom area of the storage container, which is designed as a sediment container, there is a conveying device which feeds the sediment mixture that has sunk within the storage container to the side of the washing zone, whereby the conveying device can be designed as a dosing screw in a structurally particularly simple and reliable variant.

In order to ensure that the device works reliably over the long term under automatic conditions, i.e. without the need for a large number of personnel, a particularly preferred embodiment is characterized by the fact that a vibrating rod sensor is arranged in the washing zone, the signals of which act on a control device which activates or deactivates the discharge device depending on the signals from the sensor. The sensor serves to maintain an upper level of the collection unit (sand stock) for the cleaned material. When the specified level is reached, the cleaned material is discharged using the discharge device.

As part of the automation process, it has proven to be beneficial to use a control device that activates the conveyor system in cycles after a predeterminable time interval has elapsed for a predeterminable period of time.

A particularly effective impulse flow, which ensures a particularly high degree of sand cleaning, is characterized by the presence of a control device that controls the device for generating an impulse flow

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such that a high flow velocity is generated in cycles over a relatively short period of time, for example approximately 1 second, and then a lower or no flow velocity is generated over a subsequent longer period of time, for example 10 seconds.

A particularly effective device is characterized according to the invention in that the device for generating a flow generates a liquid flow, whereby service water can preferably be used as the flow liquid. In addition to this liquid flow, a device for generating an air flow can be arranged within the washing zone according to an advantageous embodiment of the device according to the invention.

The device according to the invention enables an improvement in circulation by mixing and thus cleaning the sediment mixture or the sand. A particularly preferred embodiment of the device according to the invention is characterized in that the nozzle unit is designed as drive nozzles based on the principle of a water jet pump. This allows aeration and turbulence of the sand-wastewater mixture to be implemented in a structurally simple manner. The necessary air is sucked in via the drive nozzles by the water flow generated by the direction of introduction and introduced together as an air-water mixture.

A particularly preferred robust embodiment of the device according to the invention is characterized in that the discharge device is designed as a discharge screw.

Further embodiments and advantages of the invention result from the features further listed in the claims and from the exemplary embodiments given below. 35

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The features of the claims may be combined in any way, provided they are not obviously mutually exclusive.

SHORT DESCRIPTION OF THE DRAWING

The invention and advantageous embodiments and further developments of the same are described and explained in more detail below using the examples shown in the drawing. The features shown in the description and the drawing can be used individually or in groups in any combination according to the invention. They show:

Fig. 1 highly schematic device for separating and cleaning a sand-water-organic mixture with a separate washing zone, a device for generating an upflow pulse flow and a vibrator unit,

Fig. 2 schematic diagram of the mixture layers forming during the treatment,

Fig. 3 schematic flow velocity-time diagram of the impulse flow and

Fig. 4 schematic structural representation of a device according to Fig. 1.

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WAYS TO CARRY OUT THE INVENTION

In the following, we assume a sand-wastewater mixture that needs to be separated and cleaned.

According to the schematic representation in Fig. 1, the device 10 for cleaning and separating the sand has a storage container 16, which is filled with the sand-wastewater mixture from the top via an inlet 12. The filling can also take place from the side. In the bottom area, the storage container 16 has a conveyor device 30 running _from left to right, which is designed as a conveyor screw and conveys in the conveying direction T. Inside the storage container 16, the sand settles on the underside in the area of the conveyor screw 30 according to the schematically shown arrows A, ie

the storage tank 16 is designed as a sediment collection tank. The conveyor screw 30 transfers the sand into a container 24 arranged to the right of the storage tank 16 in Fig. 1. In the left edge area, the storage tank 16 has an outlet 14 for conveying water, by means of which the conveying water can be drawn off from the container 16 and fed back into the cleaning circuit. In the normal case, fresh water is added.

In the right-hand edge area, the storage tank 16 has an outlet 28 through which the organic washed-out components can drain off and be fed to the biological treatment stage or collected separately. The organic components can drain off from the container 24 additionally or alternatively via the overflow 42 shown schematically at the top right in Fig. 1. The level of the overflow 42 is slightly below the level of the sand-wastewater mixture filled into the storage tank 16. The water level in the storage tank 16 is shown schematically by the black arrowhead 44. 35

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By means of the conveyor screw 30, the sand sedimented in the storage container is pressed laterally into the container 24 in the upper area of a washing zone 36. In the lower area of the container 24 there is a device 20 for generating an upflow, whereby this upflow works in a pulsed manner, which will be described further below. Just above the device 20 there is a vibrator unit which ensures homogenization of the sand collected in the container. In the example shown, the vibrator unit 26 has vibrator plates which are excited to vibrate. Furthermore, a vibrating rod sensor 32 is arranged within the container 24.

Below the device 20, a discharge device is schematically arranged, shown by an arrow 22 pointing upwards to the right, which, depending on the fill level of the container 24, removes the cleaned sand accumulated in the lower sand trap 50.

Furthermore, Fig. 1 schematically shows a control device 40, which receives a signal from the vibrating rod sensor and which acts on the conveyor screw 30, the vibrator unit 26, the device 20 and the discharge device 22. The detailed design will be described in more detail with reference to Fig. 4.

The actual washing zone 36 within the container 24 is thus located above the device 20.

Fig. 2 shows schematically, using a block diagram, which individual material layers form within the container 24 after a certain period of time when a sand-wastewater mixture is added. In the upper area there is the so-called "organic matter", which is removed or expelled upwards by the side addition and then subjected to biological

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clarification process. A so-called suspended matter layer forms underneath, within which the fine sand or silt is suspended. The actual coarse material, i.e. the sand, is located in the lower area and, according to the schematic representation in Fig. 1, collects in the lower area of the container 24 up to a level 54, which is determined by the vibrating rod sensor 32.

Above the device 20 there is sand that is currently being cleaned, and in the sand trap 50 below there is cleaned sand.

Fig. 3 shows schematically the flow velocity-time diagram of the pulse flow formed by the device 20 (arrows I in Fig. 1). Over a relatively short period of time T2, a relatively high flow velocity is generated within the sand trap 24. The period of time T2 is preferably about 1 second. This short pulse-like increased flow velocity is repeated in cycles after the cycle time Tl. The cycle time Tl is preferably about 10 seconds. By forming a pulse flow, a particularly high degree of cleaning of the sand is achieved.

Fig. 4 shows a schematic design of a device 10 for cleaning a sand-wastewater mixture. The same components and parts as in Fig. 1 have the same reference numerals and are not explained again.

As shown in Fig. 4, a schematically shown motor 38 is coupled to the vibrator unit 26 via a shaft 27, which causes the vibrator unit 26 to vibrate. The motor 38 is controlled by the control device 40. The vibrations can also be generated in another way.

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A vibrating rod sensor 32 extends into the interior of the container 24, essentially parallel to the shaft 27, and carries out a damping level measurement inside the container in the area where the cleaned sand accumulates. This vibrating rod sensor 32 is also coupled to the control device 40. It sends its signals to the control device 40 and the control device 40 then controls the drive unit 46 of the discharge device 22, which is designed as a discharge screw. If the measurement of the sensor 32 shows a high level of damping, i.e. an increased accumulation of sand, the drive unit 46 is activated and washed sand is drawn off from the bottom of the sand trap 50, discharged and statically dewatered and delivered to the collection container 34 in a touch-dry state. If a low level of damping is measured, the drive unit 46 remains deactivated.

The vibrating rod sensor 32 thus determines the level up to which coarse material can accumulate.

The device 20 for generating the pulse-like upflows within the container 24 has a nozzle base with grid-like nozzle supports, whereby the sand can settle downwards through this nozzle base. The device 20 is also controlled by the control device 40 for generating the pulse flow described above.

Finally, the control device 40 controls the drive unit 31 of the conveyor device 30. In this case, the conveyor screw is activated for a predeterminable period of time, for example, every 200 seconds, and then conveys the sand that has sunk into the storage container 16 sideways into the washing zone 36. Due to the upflow in the area of the washing zone 36, the organic matter collects in the upper area of the storage container and is discharged to the outside through the outlet 28, as already described. -11-

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It is not absolutely necessary that a common control device 40 must be present. For example, the vibrator unit 26 with motor 38 or the device for generating a pulse flow or the drive unit 31 of the device 30 can each have its own control device.

Claims (1)

-1-CLAIMS 01) Device (10) for separating and cleaning a suspended matter, sediment and waste water mixture, in particular a sand-water-organic mixture, with - a storage tank (16) to which the mixture is fed via an inlet (12) and conveying water is drawn off via an outlet (14), - a device (20) for generating a flow acting on the mixture, and - a discharge device (22) for discharging the separated and cleaned sediment mixture, characterized in that a separate washing zone (3 6) is present, to which the mixture or the sediment mixture that has sunk within the storage container (16) is fed laterally via a feed (52), - a collection unit (50) is arranged below the washing zone (36) and the discharge unit (22) for the cleaned material is arranged thereafter, - the device (20) for generating a flow is arranged above the discharge unit (22) and below the lateral feed (52), the device (20) being operated using the current pulse method, and - a vibrator unit (26) is present within the washing zone (36) for homogenizing the sediment mixture accumulating within the washing zone (36). 02) Device according to claim 1, characterized in that in the bottom area of the storage container (16), which is designed as a sediment collecting container, a conveying device (30) is provided, which conveys the sediment mixture sunk within the storage container (16) to the side of the Washing zone (3 6). -2- EGN-IOSgDE _### 29 November 1996 .*I &iacgr;" *· * · ··· -2- 03) Device according to claim 2, characterized in that the conveying device (30) is designed as a dosing screw.
05 04) Device according to one or more of the preceding claims, characterized in that a vibrating rod sensor (32) is arranged projecting into the washing zone (36), the signals of which are sent to a control device (40) which activates or deactivates the discharge device (22) depending on the signals from the sensor (32). 05) Device according to claim 2 and/or 3, characterized in that a control device (40) is present which activates the conveyor device (30) in cycles after expiration of a predeterminable time interval for a predeterminable period of time. 06) Device according to one or more of the preceding claims,
characterized in that a control device (40) is provided which controls the device for generating a pulse flow in such a way that a high flow velocity is generated in cycles over a relatively short period of time (T2) and then a low or no flow velocity is generated over a subsequent longer period of time (T1-T2). 29 November 1996 "",,". .&iacgr;··;**; ·*. -3- 07) Device according to one or more of the preceding claims, characterized in that the device (20) for generating a flow generates a liquid flow. 08) Device according to one or more of the preceding claims, characterized in that a device for generating an air flow is arranged in the region of the washing zone (36). 09) Device according to one or more of the preceding claims, characterized in that the discharge device (22) is designed as a discharge screw. 10) Device according to one or more of the preceding claims, characterized in that the device (20) for generating a flow has a nozzle base.