DE20321422U1 - Phosphate elimination device by a simple metering unit in pilot or small-sized sewage treatment plants, comprises a container for storing precipitating agent, a metering unit with a metering chamber, and a discharge- and a feed line - Google Patents

Abstract

The phosphate elimination device by a simple metering unit for the dosage of a precipitating agent in pilot or small-sized sewage treatment plants with an air compressor/blower, comprises a container for storing precipitating agent, a metering unit with a metering chamber, and a discharge- and a feed line. The metering container (5) exhibits a round, multi-edged or other geometrical form. The dosage of the precipitating agents is controlled with respect to time, wastewater quantity or other control variables. The phosphate elimination device by a simple metering unit for the dosage of a precipitating agent in pilot or small-sized sewage treatment plants with an air compressor/blower, comprises a container for storing precipitating agent, a metering unit with a metering chamber, and a discharge- and a feed line. The metering container (5) exhibits a round, multi-edged or other geometrical form. The dosage of the precipitating agents is controlled with respect to time, wastewater quantity or other control variables. The control procedure helps to easily calculate the used-up and/or the remaining quantity of the precipitating agent from the number of accomplished metering steps. The operator/maintenance personnel is informed well in advance of the needed refilling of the precipitating agents and a loss of the phosphate elimination through lack of the precipitating agent is avoided. The procedure/the device is equipped with an own control mechanism. The metering container is provided with firm or flexible feed- and/or discharge- compressed air lines. The metering container is built with a variable volume to easily adjust the metering volume per metering step. The adjustment of metering volume takes place in a procedure arrangement through a movable, adjustable piston in the metering container. The metering container in the procedure arrangement is accurately led over a guidance rod in a storage vessel (1). Length of a feed line- (6) and a discharge compressed air line (4) projecting into the metering container are variable in the procedure arrangement. In a procedure arrangement, the height of the metering container towards a float (2) is adjustable, to change the fluid level of the metering container. A compressed air leaves through the downwardly extended feed line and leads to a thorough mixing of the precipitating agents in the storage vessel. The float function is replaced by the buoyancy of the metering container. All or every feed- and discharge-lines are equipped with flaps, valves or other locking arrangement. The storage vessel is provided with a refilling line or mechanism, to refill a used-up quantity of the precipitating agent. The lid of the storage vessel is provided with one or more aeration and/or deaeration devices, and is implemented as a flap or screw-type, or in a movable or detachable manner. The components of the device are made of plastic or other component and/or material. The storage vessel is provided with a holding device, to fix or fasten the wastewater treatment plant. The compressed air needed for the operation of the metering chamber is obtained from air supply of the blower membranes or the air jet lifts for feed. The procedure/the device is used in arrangements without the application of a blower. A simple and an accurate dosage of the supplied waste water quantity corresponding to the small-scale sewage treatment plant take place to avoid both an under- and an overdosage of the precipitating agent in connection with a control mechanism of small sewage treatment plants by a pressure sensor device in a procedure arrangement.

Description

small wastewater treatment or small wastewater treatment plants decentralized wastewater disposal in rural areas, in those for economic or other reasons out no sewer connection is present or is or can be made.

Here will be out of the existing legal obligations resulting need for wastewater treatment by small sewage treatment plants realized.

at wastewater treatment with small sewage treatment plants or small sewage treatment plants stands for the elimination of organic wastewater ingredients as well the nitrogen compounds so far in the foreground. The elimination of phosphorus in small sewage treatment plants or small sewage treatment plants is not yet realized in the required manner.

The Elimination of phosphorus is usually done by chemical Precipitation. This means that by adding a precipitant in conjunction with the water contained in the wastewater is an insoluble compound. By sedimentation in connection with the sludge disposal is Phosphor removed from the wastewater treatment plant. The elimination of the parameter phosphorus is due to the previously required elaborate Dosing technique of a precipitant a not yet sufficiently solved Problem in small sewage treatment plants or small sewage treatment plants represents.

small wastewater treatment are in more diverse Technically differentiated equipped. Almost everyone is in common Plants the meanwhile high use of technical components (eg blower, Pumps, float switches etc).

There the small sewage treatment plants in the vast majority operated by persons who are by the procedural procedures Understand a lot, it is necessary to ensure the plants are largely reliable to ensure lasting functionality.

Of the However, the invention described herein is based on the idea For the first time in a simple way a phosphorus elimination in small sewage treatment plants or small sewage treatment plants to operate. The invention is based essentially on an innovative dosing unit in wastewater treatment plants, preferably in small sewage treatment plants and small sewage treatment plants with SBR method, preferably with at least one air compressor / blower, consisting from a container for storing the precipitant, a dosing unit with a metering chamber, a supply and a efferent Line and a filling line.

One significant proportion of SBR plants is using a blower / compressor for oxygen supply and operation of compressed air lifting systems (mammoth pumps) operated. For metering, the blower power in a preferred Variant of the method to be used.

For example, an additional outlet with a solenoid valve is installed in the air line leaving the blower / compressor on the pressure side. From here leads a line ( 3 ) to that in the reservoir ( 1 ) located dosing ( 5 ). In the reservoir ( 1 ), the precipitant needed for phosphate precipitation is stored. In one embodiment of the method, the dosing container ( 5 ) with one or more buoyancy bodies ( 2 ) at the same height as the liquid level in the storage container ( 7 ) held. By this preferred embodiment is achieved that the dosing ( 5 ) always at a certain height to the changing liquid level in the reservoir ( 7 ) is held.

At the dosing tank ( 5 ) is a filling line ( 6 ) as well as an outgoing compressed air line.

In depressurized state, the precipitant flows out of the reservoir ( 7 ) via the filling line ( 6 ) into the dosing container ( 5 ). The filling quantity is defined by the position of the dosing container ( 5 ) to the liquid level in the reservoir ( 7 ). The dosing container ( 5 ) only fills up to the metering container ( 5 ) surrounding liquid level in the reservoir ( 7 ). Now opens the control of the wastewater treatment plant or another control (eg timer or other control) the compressed air valve with the compressor / blower is running, via the supplying compressed air line ( 3 ) the dosing container ( 5 ) is pressurized. Because in the dosing container ( 5 ) precipitants are not through the in the dosing ( 5 ) projecting filling line ( 6 ) can flow back, this is in the dosing ( 5 ) precipitant through the laxative compressed air line ( 4 ) from the dosing tank ( 5 ) and thus passes through the laxative compressed air line ( 4 ) to the metering point in the wastewater treatment plant. After completing the dosing process, the compressed air valve closes the incoming compressed air line ( 3 ). The existing pressure can be reached via the discharging compressed air line ( 4 ) or the filling line ( 6 ) dismantle. Then the dosing tank fills ( 5 ) via the filling line ( 6 ) again exactly on the same liquid level. This ensures that the same amount of precipitant is added to the wastewater treatment process during each dosing process. In order to supply the wastewater treatment process with the total amount of precipitant required, the number of metering operations can be varied accordingly.

In order to are the controls of small sewage treatment plants and small sewage treatment plants on very simple and inexpensive Way able to remove phosphates from the sewage.

• – Die Dosierung des Fällmittels über Zeit, Abwassermenge oder sonstige Steuergrößen vorzunehmen.
• – Die Größe und Form des Dosierbehälters (5) ebenso wie die anderen Komponenten können je nach Erfordernis variieren. So kann der Dosierbehälter (5) beispielsweise auch eine runde, vieleckige oder sonstige geometrische Form aufweisen.
• – Über die Anzahl der durchgeführten Dosiervorgänge kann die Steuerung auf einfache Weise die verbrauchte bzw. die noch vorhandene Fällmittelmenge errechnen. Damit kann der Betreiber/Wartungsdienst bereits frühzeitig über das notwendigen Nachfüllen des Fällmittels informiert werden und ein Ausfall der Phosphatelimination durch Fällmittelmangel kann vermieden werden.
• – Bestehende Steuerungen können verwendet werden oder das Verfahren/die Vorrichtung kann mit einer eigenen Steuerung ausgerüstet werden.
• – Der Dosierbehälter (5) kann mit festen oder flexiblen zu- und/oder abführenden Druckluftleitungen versehen sein.
• – Der Dosierbehälter (5) kann mit einem variablen Volumen gebaut werden, um auf einfache Weise das Dosiervolumen pro Dosiervorgang anzupassen. Dies kann in einer beispielhaften Verfahrensausgestaltung durch einen beweglichen, verstellbaren Kolben im Dosierbehälter (5) geschehen.
• – Der Dosierbehälter (5) kann in einer Verfahrensausgestaltung an einer Führungsstange im Vorratsbehälter (1) exakt geführt werden.
• – Die Füllleitung (6) kann in einer Verfahrensausgestaltung ebenfalls bzgl. der in den Dosierbehälter (5) hineinragenden Länge veränderbar sein.
• – Die abführende Druckluftleitung (4) kann in einer Verfahrensausgestaltung ebenfalls bzgl. der in den Dosierbehälter (5) hineinragenden Länge veränderbar sein.
• – Der Dosierbehälter (5) kann in einer Verfahrensausgestaltung zum Auftriebskörper (2) hin in der Höhe verstellbar sein, um den Flüssigkeitsspiegel im Dosierbehälter (8) verändern zu können.
• – Durch die Füllleitung (6) kann ebenfalls Druckluft austreten und zu einer Durchmischung des Fällmittels im Vorratsbehälter (1) führen. Hierzu kann die Füllleitung (6) nach unten verlängert werden.
• – Durch das Weglassen der Auftriebskörper (2) kann deren Funktion durch eigenen Auftrieb des Dosierbehälters (5) ersetzt werden.
• – Alle oder einzelne zu- und abführende Leitungen können mit Klappen oder Ventilen oder anderen Verschlussorganen ausgestattet sein.
• – Der Vorratsbehälter (1) kann mit einer Nachfüllleitung oder einer Nachfülleinrichtung versehen werden, um verbrauchtes Fällmittel nachzufüllen.
• – Der Deckel des Vorratsbehälter (1) kann mit einer oder mehreren Be- und/oder Entlüftungsvorrichtungen versehen sein.
• – Der Deckel des Vorratsbehälter (1) kann verschraubt, klappbar oder abnehmbar ausgeführt sein.
• – Der Vorratsbehälter (1) kann aus Kunststoff, PE oder einem sonstigen Bau- oder Werkstoff oder einer Kombination daraus bestehen.
• – Der Dosierbehälter (5) kann aus Kunststoff, PE oder einem sonstigen Bau- oder Werkstoff oder einer Kombination daraus bestehen. Gleiches gilt für die weiteren Komponenten der Vorrichtung/des Verfahrens.
• – Der Vorratsbehälter (1) kann mit einer Haltevorrichtung versehen sein, um in den Abwasserbehandlungsanlagen befestigt oder fixiert zu werden.
• – Der Vorratsbehälter (1) kann außerhalb der Abwasserbehandlungsanlage frei, in einem separaten raumbildenden Gehäuse oder einem bereits bestehenden raumbildenden Gehäuse (z. B. Schaltschrank) eingebaut werden kann.
• – Das Verfahren/die Vorrichtung kann auch dort eingesetzt werden, wo bisher kein Gebläse eingesetzt wird. Durch eine einfach nachrüstbare Vorrichtung zum Erzeugen von Druckluft (z.B. kleiner Kompressor) kann das Verfahren/die Vorrichtung in gleicher Weise bei allen marktüblichen Kleinkläranlagen/kleinen Kläranlagen betrieben werden.
• – Bestehende Anlagen können auf einfache Weise nachgerüstet werden.

Embodiments of the method are:

• - Make the dosage of the precipitant over time, waste water quantity or other control variables.
• - The size and shape of the dosing tank ( 5 ) as well as the other components may vary as required. So the dosing container ( 5 ), for example, also have a round, polygonal or other geometric shape.
• - About the number of dosing performed, the controller can easily calculate the consumed or the remaining amount of precipitant. Thus, the operator / maintenance service can be informed early on the necessary refilling of the precipitant and a loss of phosphate elimination by precipitant deficiency can be avoided.
• - Existing controls can be used or the procedure / device can be equipped with its own control.
• - The dosing tank ( 5 ) can be provided with fixed or flexible incoming and / or outgoing compressed air lines.
• - The dosing tank ( 5 ) can be built with a variable volume to easily adjust the dosing volume per dosing. In an exemplary embodiment of the method, this can be achieved by a movable, adjustable piston in the dosing container (FIG. 5 ) happen.
• - The dosing tank ( 5 ) can in a process design on a guide rod in the reservoir ( 1 ) are guided exactly.
• - The filling line ( 6 ) can in a process configuration also with respect. In the dosing ( 5 ) be projecting length changeable.
• - The evacuating compressed air line ( 4 ) can in a process configuration also with respect. In the dosing ( 5 ) be projecting length changeable.
• - The dosing tank ( 5 ) can in a process configuration to the buoyant body ( 2 ) in height adjustable to the liquid level in the dosing ( 8th ) to change.
• - Through the filling line ( 6 ) can also escape compressed air and to a mixing of the precipitant in the reservoir ( 1 ) to lead. For this purpose, the filling line ( 6 ) are extended downwards.
• - By omitting the buoyancy bodies ( 2 ) can their function by own buoyancy of the dosing ( 5 ) be replaced.
• - All or individual incoming and outgoing lines can be equipped with flaps or valves or other closing organs.
• - The reservoir ( 1 ) may be provided with a refill line or a refill device to refill spent precipitate.
• - The lid of the reservoir ( 1 ) may be provided with one or more loading and / or venting devices.
• - The lid of the reservoir ( 1 ) can be screwed, hinged or removable.
• - The reservoir ( 1 ) may consist of plastic, PE or other construction or material or a combination thereof.
• - The dosing tank ( 5 ) may consist of plastic, PE or other construction or material or a combination thereof. The same applies to the other components of the device / the method.
• - The reservoir ( 1 ) may be provided with a holding device to be fixed or fixed in the waste water treatment plants.
• - The reservoir ( 1 ) can be freely installed outside the waste water treatment plant, in a separate space-forming housing or in an already existing space-forming housing (eg control cabinet).
• - The method / the device can also be used where previously no fan is used. By a simple retrofittable device for generating compressed air (eg small compressor), the method / the device can be operated in the same way in all customary small wastewater treatment plants / small wastewater treatment plants.
• - Existing systems can be easily retrofitted.

Under The No. 10258349.8 was already the control of small wastewater treatment plants Patent pending by means of pressure sensor. In conjunction with this procedure can be a simple but accurate in a process design Dosage according to the treatment plant supplied Wastewater quantity carried to both a sub-and an overdose of precipitant to avoid.

1

reservoir

2

Buoyancy body (optional)

3

feeding compressed air line

4

outgoing Compressed air line

5

dosing

6

filling line

7

liquid level reservoir

8th

liquid level dosing

10

flap (Optional)

11

vent

Claims (23)

Apparatus for the elimination of phosphate by means of a simple dosing unit for dosing precipitants in wastewater treatment plants, preferably in small sewage treatment plants and small sewage treatment plants, consisting of a container for storing the precipitant, a dosing unit with a metering chamber, a supply and a efferent Line and a filling line. The preferred application is in small sewage treatment plants and small sewage treatment plants with SBR method, preferably with at least one air compressor / blower. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized in that the size and shape of the dosing ( 5 ) as well as the other components may vary as required. So the dosing container ( 5 ), for example, also have a round, polygonal or other geometric shape. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that the dosage of the precipitant over time, Sewage or other control variables can be made. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that over the number of dosing operations performed Control in a simple way the used or the still existing coagulant can calculate. This allows the operator / maintenance service already early on the necessary refills the precipitant be informed and a loss of phosphate elimination by precipitant deficiency can be avoided. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that existing controls can be used or the procedure / Device can be equipped with its own control. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the dosing tank ( 5 ) can be provided with fixed or flexible supply and / or laxative compressed air lines. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the dosing tank ( 5 ) can be built with a variable volume to easily adjust the dosing volume per dosing. In an exemplary embodiment of the method, this can be achieved by a movable, adjustable piston in the dosing container (FIG. 5 ) respectively. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the dosing tank ( 5 ) in a process design on a guide rod in the reservoir ( 1 ) can be performed exactly. Device for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the filling line ( 6 ) in a process configuration with respect to the in the dosing ( 5 ) protruding length can be changed. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized in that the laxative compressed air line ( 4 ) in a process configuration with respect to the in the dosing ( 5 ) protruding length can be changed. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the dosing tank ( 5 ) in a process configuration for the buoyant body ( 2 ) in height can be adjusted to the liquid level dosing ( 8th ) to change. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that through the filling line ( 6 ) Leak compressed air and to a mixing of the precipitant in the reservoir ( 1 ) can lead. For this purpose, the filling line ( 6 ) are extended downwards. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that by omitting the buoyancy bodies ( 2 ) whose function by own buoyancy of the dosing ( 5 ) can be replaced. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that all or individual incoming and outgoing lines with flaps, Valves or other closure devices may be equipped. Device for phosphate elimination in Ab Water treatment plants according to one or more of the preceding claims, characterized in that the storage tank ( 1 ) can also be provided with a refill line or a refill to refill spent precipitant. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the lid of the reservoir ( 1 ) may be provided with one or more loading and / or ventilation devices. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the lid of the storage container ( 1 ) can be screwed, hinged, movable or removable. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized in that the storage tank ( 1 ) may consist of plastic, PE or other construction or material or a combination thereof. Apparatus for the elimination of phosphates in wastewater treatment plants according to one or more of the preceding claims, characterized in that the dosing tank ( 5 ) may consist of plastic, PE or other construction or material or a combination thereof. The same applies to the other components of the device / the method. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized in that the storage tank ( 1 ) may be provided with a holding device to be fixed or fixed in the waste water treatment plants. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that the compressed air required for operating the metering chamber from an existing compressed air line (for example, to supply air to the aerator membranes or the compressed air lift to feed) can be removed. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that the method / device can also be used there, where so far no fan was used. By an easy to retrofit device for generating compressed air (e.g., small compressor) may be the method / apparatus in the same way for all customary small sewage treatment plants and small sewage treatment plants operate. Apparatus for the elimination of phosphate in wastewater treatment plants according to one or more of the preceding claims, characterized that in conjunction with a control of small sewage treatment plants using a pressure sensor in a process design a simple, but exact dosage according to the wastewater treatment plant supplied wastewater is carried out to both a under- and an overdose of precipitant to avoid.