DE3621724A1 - Fully automatic back-washable filter for liquid media - Google Patents

Abstract

In a fully automatic back-washable filter for liquid media comprising a cylindrical shell which is subdivided by a horizontally arranged plate into two compartments, the bottom compartment being provided with an inlet nozzle for the medium to be purified and the top compartment being provided with an outlet nozzle for the purified medium, and comprising filter elements which are arranged in the top compartment on the plate concentrically with the shell axis and are connected via orifices in the plate to the bottom shell space, in which is arranged a rotatably mounted tubular rotation arm, the upper orifice of which lies against the underneath of the plate and can be transported beneath the orifices in the plate and the lower orifice of which rotation arm is connected to a discharge nozzle which is connected to the atmosphere and can be shut off by a valve, according to the invention it is provided that the rotation arm is designed in such a way that a turning moment is generated in it by the flow of the back-wash medium which sets the rotation arm in rotation, during which the filter elements are successively freed from the contaminants by the back-wash medium flowing through.

Description

The invention relates to a fully automatic, self-cleaning backwash filter according to the generic term of claim 1.

Such a filter is known from DE-GM 83 06 970. It is placed in a dirty medium, e.g. sewage leading pipeline installed. The dirty medium flows through the inlet connector into the lower housing area and enters the through the openings in the plate upper housing space after it has the filter elements, in general filter candles. The cleaned Medium leaves the housing via the outlet connection. The Device for measuring differential pressure measures continuously the pressure difference between the lower and upper housing area. Because the filter candles clog up more and more, the differential pressure finally reaches a value at which the rotation arm is rotated and the backwash valve is opened at the same time. Thereby the upper housing space is connected to the atmosphere. The resulting pressure difference leaves cleaned medium through the filter candles, the rotating arm and the open Drain the backwash valve to the outside. The in the filter candles present and the filter candles cleaned. To drive the rotating arm serves an electric motor in the previously known backwash filter, which has a motor pinion, which with a spur gear combs on the rotation arm.

The disadvantage of such a backwash filter is one that drives the rotary arm to external energy is instructed. However, the supply of external energy is  often problematic, since the backwash filters are often used long overland pipelines are far away. This further complicates the maintenance of the drive. The moving drive elements, but also the motor and the filter candles are partially cleaned Medium, partly due to the weathering of the corrosion suspended so that such regular maintenance is inevitable. However, this creates considerable Downtimes of the filter.

The invention is therefore based on the object To design backwash filters of the type mentioned at the beginning that the drive of the rotary arm regardless of External energy and largely maintenance-free operation is guaranteed.

The invention solves this problem with the aid of the features of the characterizing part of claim 1. Further advantageous embodiments of the invention are the subject of subclaims.

Due to the special design of the rotating arm it is possible from the filter cartridges and the openings in the Plate flowing into the upper opening of the rotating arm To conduct backwash liquid so that the wall of the horizontal section of the rotary arm as Baffle serves for the flowing backwash liquid. The force exerted on this impact surface exerts via the lever arm formed by the horizontal section a torque on the rotary arm. In the course of Rotation movement moves the upper opening of the rotation arm among those arranged concentrically to the housing axis  Openings in the plate. The backwash liquid cleans during the rotation of the rotating arm all filter candles from those collected in them Contamination until the differential pressure between the upper and lower housing area again reached a value has a closing of the Backwash valve causes. Another way to The end of the backwashing process also consists in provide a timer for this. The actuation of the Backwash filter can be on electrical, but also on pneumatic ways happen.

To compensate for any imbalance or to compensate the flow forces at the housing entrance, the rotational movement counteract the rotation arm is horizontal on the extending section of the rotary arm a wing arranged. This wing is from the input flow of the contaminated medium flows and supports the Rotational movement of the rotating arm.

According to claim 5 are as an additional drive Rotational arm arranged on the shaft radial wing. These wings are from the input flow of the flow of contaminated medium. The on the wing surfaces acting forces cause a rotary movement of the Rotation arm. To improve the effect, the Claim 6 before that for the flow against the wing in the lower A baffle is arranged next to the inlet port in the housing space is. This baffle deflects the flow so that only the wings are flown, each in one Half space of the housing.  

The same effect results if according to claim 7 the inlet port tangential in the housing wall is arranged.

In another embodiment of the invention provided that the horizontal portion of the rotatin arm by a horizontal one Wall into a lower and an upper pipe cross section is divided, with the lower pipe cross section in lower housing space is open and in horizontal section of the rotating arm flows. Through that in the rotating arm at the mouth of the lower one Pipe cross-section flowing medium is created in this lower pipe cross section a negative pressure, the contaminated Sucks in medium from the lower housing area. These Suction also supports the rotary drive of the Rotation arm.

To avoid a too high rotation speed of the Rotational arm provides claim 9 that in the camp a braking device is provided for the rotary arm. A speed control is also by throttling of the backwash valve possible. To be a continuous To achieve the turning process, the filter elements are so close arranged together that the flow into the upper Opening of the rotary arm is not interrupted.

The invention is described below with reference to drawings shown and explained in more detail. Show it

Fig. 1 backwash filter in transparent representation,

Fig. 2 cross section through a backwash filter in the region below the plate,

Fig. 3 are partial view of the lower housing space from a direction different from the Fig. 1 view,

Fig. 4 is a cross-section through backwash filter with fixed to the rotary shaft of the rotary arm wings,

Fig. 5 illustration according to Fig. 4 with tangentially disposed filler neck,

Fig. 6 partial view of the lower housing chamber having attached to the rotary shaft of the rotary vanes are blown from below,

Fig. 7 cross-section through the filter housing (embodiment according to Fig. 6),

Fig. 8 partial representation of the lower housing space with inserted in the horizontal section of the tube partition.

In the drawings, the backwash filter according to the invention is provided with the reference symbol ( 1 ). It essentially consists of a cylindrical housing ( 2 ), which consists of two housing parts ( 3 and 4 ), which are separated from each other by means of a plate ( 5 ) and flanged together at ( 6 ). Openings ( 8 ) are arranged in the plate ( 5 ) concentrically around the housing axis ( 7 ). Filter candles ( 9 ) are arranged in alignment with the openings ( 8 ) in the upper housing space ( 3 ) on the plate ( 5 ). In the wall of the lower housing part ( 4 ) there is an inlet connection ( 10 ) and in the wall of the upper housing part ( 3 ) there is an outlet connection ( 11 ). A rotating arm ( 12 ) is arranged in the lower housing space ( 4 ). This rotary arm ( 12 ) is rotatably supported in bearings ( 13 and 14 ). The axis of rotation coincides with the housing axis. The rotation arm ( 12 ) is constructed as follows: Aligned with the openings ( 8 ) in the plate ( 5 ), a first tubular section ( 15 ) runs vertically parallel to the housing axis ( 7 ). Following this, a further section ( 16 ) runs obliquely downwards in the direction of a horizontally arranged intermediate piece ( 17 ) such that the mouth of the section ( 16 ) ends at the outer end of the intermediate piece ( 17 ). At the opposite end of the intermediate piece ( 17 ) a wing ( 18 ) is arranged at the level of the inlet connector ( 10 ). From the center of the intermediate piece ( 17 ), another tubular section ( 19 ) of the rotating arm ( 12 ) leads vertically and coaxially to the housing axis ( 7 ) through the bottom ( 20 ) of the lower housing part ( 4 ) into a flanged housing ( 21 ). This housing ( 21 ) is provided with an opening ( 22 ) into which a pipe socket ( 23 ) opens into which a backwash valve ( 24 ) is installed. The rotating shaft ( 26 ) of the rotating arm ( 12 ) is mounted in the bearing ( 14 ) in the bottom ( 25 ) of the housing ( 21 ). A brake device ( 27 ), not shown, is provided in the bearing ( 14 ). The longitudinal axes of the sections ( 15 and 17 ) of the rotary arm ( 12 ) represent straight lines that run skew to one another.

In FIG. 4, the lower housing part (4) is shown in plan view. On the shaft ( 26 ) of the rotary arm ( 12 ), vanes ( 28 ) designed in the manner of blades are attached radially above the intermediate piece ( 17 ). These vanes ( 28 ) are flowed against by the medium to be filtered flowing in at ( 10 ), which leads to a rotary movement of the rotary arm ( 12 ). In order to direct the flow into only one half of the lower housing part ( 4 ), a baffle ( 29 ) is arranged on the inner housing wall on the right of the inlet connection ( 10 ) in the inflow direction.

In the example of FIG. 5, this guide plate ( 29 ) has been omitted. Instead, the inlet connection ( 10 ) is arranged on the housing in such a way that the medium to be filtered flows tangentially into the lower housing space ( 4 ).

In FIG. 6, a further embodiment of the invention is shown. In this case, blades ( 30 ) which are inclined are also arranged radially on the shaft ( 26 ) directly below the plate ( 5 ). The medium to be cleaned flows against these blades ( 30 ), which leads to a rotary movement of the rotating arm ( 12 ).

Figure 7 shows a top view of the wings ( 30 ). Finally, Figure 8 shows another embodiment of the invention. Here, the intermediate piece ( 16 ) of the rotary arm ( 12 ) is carried out horizontally. The section ( 16 ) is divided in the lower half of the cross section by a sheet ( 31 ) into two sections. The lower cross section is open to the lower housing space ( 4 ) and opens into the section ( 19 ) of the rotary arm ( 12 ). In all embodiments of the rotary arm (12) of the rotary arm are provided (12) openings (32) in the lower portion (19) which open into the housing (21).

The housing (2) a device not shown for differential pressure measurement of the pressure difference between the lower housing space (4) and the upper housing space (3) is arranged. This device is electrically or pneumatically connected to the backwash filter ( 24 ) in order to open or close it.

The operation of the backwash filter shown is as follows: The medium to be filtered flows through the inlet connection ( 10 ) into the lower housing space ( 4 ) and from there through the openings ( 8 ) in the plate ( 5 ) and the filter candles ( 9 ) into the Upper housing space ( 3 ), where the cleaned medium leaves the housing ( 2 ) through the outlet nozzle ( 11 ). During the filtering process, the impurities settle in the filter candles ( 9 ) and become more and more clogged over time. The device for measuring the differential pressure continuously measures the pressure difference between the housing space ( 3 ) and the housing space ( 4 ). At a predetermined differential pressure, which is dependent on the contamination of the filter cartridges ( 9 ), the differential pressure measuring device actuates a switch which gives the signal to open the backwash filter ( 24 ). At this moment the upper housing space ( 3 ), with the rotating arm ( 12 ), the housing ( 21 ) and the pipe socket ( 23 ) is connected to the atmosphere. The pressure difference achieved in this way allows cleaned medium to flow from the housing part ( 3 ) through an opening ( 8 ) into the rotary arm ( 12 ), after which it flows through the openings ( 32 ), the opening ( 22 ) in the housing ( 21 ) and the pipe socket ( 23 ) leaves outside. On its way through the rotating arm ( 12 ), the flowing medium strikes a wall of the horizontal section ( 17 ) of the rotating arm ( 12 ), whereby a torque is exerted on the rotating arm ( 12 ). As a result, the rotary arm is moved with its upper opening onto an adjacent opening ( 8 ) in the plate ( 5 ), where the process is repeated. Over time, the upper opening of the rotating arm ( 12 ) passes under all openings ( 8 ) and pulls the cleaned medium through the filter candles ( 9 ) to the pipe socket ( 23 ). The cleaned medium flowing back through the filter candles entrains the impurities in the filter candles ( 9 ). After a predetermined time or after reaching a certain differential pressure between the lower and upper housing part, the device for measuring the differential pressure switches the backwash valve ( 24 ) and closes it. On the one hand, the wing ( 18 ) on the horizontal section ( 17 ) of the rotary arm ( 12 ) serves to support the rotary movement.

However, the rotary movement can also be supported by the wings shown in FIGS. 4 to 7.

In the embodiment according to FIG. 8, this support of the rotary movement takes place in that in the lower partial cross section of the section ( 16 ) by the in the intermediate piece ( 17 ) and in the lower section ( 19 ) of the rotary arm ( 12 ) at the mouth of the lower Partial cross-section flowing medium creates a negative pressure. As a result of this negative pressure, uncleaned medium is sucked out of the housing part ( 4 ), which also strikes the wall of the intermediate piece ( 17 ) and also generates a torque.

Claims (9)

1. Fully automatic backflushing filter for liquid media, consisting of a cylindrical housing, which is a horizontally arranged plate is divided into two sub-rooms, the lower housing space being provided with an inlet connection for the medium to be cleaned and the upper housing space with an outlet connection for the cleaned medium , of filter elements, which are arranged in the upper housing space on the plate concentrically to the housing axis and are connected via openings in the plate to the lower housing space, in which a rotatably mounted tubular rotary arm is arranged, the upper opening of which rests on the underside of the plate and can be moved along under the openings in the plate and the lower opening of which is connected to a discharge port which can be shut off by a valve and communicates with the atmosphere, the rotary arm running parallel to the housing axis underneath its upper opening over part of its length d is then bent towards the interior of the housing and after a further bend runs coaxially to the housing axis, and from a device for measuring the differential pressure between the lower and the upper housing space, characterized in that the first arranged below the plate ( 5 ) Section ( 15 ) of the rotary arm ( 12 ) via an adjoining further section ( 16 ) opens in the projection perpendicular to one end of a horizontally arranged intermediate piece ( 17 ), from which a further section ( 19 ) of the rotary arm ( 12 ) extends and coaxially runs to the housing axis ( 7 ) and opens into a housing ( 21 ) which can be connected to the atmosphere via a pipe socket ( 23 ) into which a backwash valve ( 24 ) is installed. 2. Backwash filter according to claim 1, characterized in that the backwash valve ( 24 ) can be actuated by a switch of the device for the differential pressure measurement when a predetermined value is reached. 3. Backwash filter according to claim 2, characterized in that the device for differential pressure measurement is electrically or pneumatically connected to the valve ( 24 ). 4. Backwash filter according to one or more of claims 1 to 3, characterized in that on the rotary arm ( 12 ) in its horizontally extending intermediate part ( 17 ) has a wing ( 18 ) to compensate for the imbalance or to compensate for the flow forces at the housing entrance ( 10 ) is arranged. 5. Backwash filter according to one or more of claims 1 to 4, characterized in that as an additional drive of the rotary arm ( 12 ) on the shaft ( 26 ) radial wings ( 28 , 30 ) are arranged. 6. Backwash filter according to claim 5, characterized in that a baffle ( 29 ) is arranged for the flow against the wing ( 28 ) in the lower housing space ( 4 ) next to the inlet port ( 10 ). 7. Backwash filter according to claim 5, characterized in that for the flow against the wing ( 28 ) of the inlet port ( 10 ) is arranged tangentially in the housing wall. 8. Backwash filter according to one or more of claims 1 to 7, characterized in that the section ( 16 ) of the rotary arm ( 12 ) extends horizontally and this section is divided by a horizontally extending wall ( 31 ) into a lower and an upper pipe cross section, wherein the lower tube cross section to the lower housing space ( 4 ) is open and opens into the intermediate piece ( 17 ). 9. Backwash filter according to one or more of claims 1 to 8, characterized in that the rotating arm is mounted in bearings ( 13 , 14 ) and in one or both bearings of the rotating arm ( 12 ) a braking device is provided.