DE4443091C1 - Drum water filter outer rim supported by rollers held within ring rail - Google Patents

Abstract

A drum-sieve has a dia. greater than the ratio of the width of the mantle to the drum dia. (2). The rollers (7) are positioned on the drum (2) rim, whose axes of rotation are parallel to that of the axis (D1) of drum rotation, and which move within a fixed ring rail (8).

Description

The invention relates to a drum screen with a Relationship to the width of the lateral surface of larger diameter the sieve drum.

Drum screens are used to remove dirt particles Liquids, especially for water filtration. The System of a drum screen consists of one slow by one horizontal drum axis rotating Sieve drum with its lower part in the water dives. The water loaded with dirt particles arrives via one or more inlet channels in the drum screen and flows through the mesh of the outer surface of the Sieve drum. The dirt particles attached to the mesh are removed from the water by rotating the sieve drum lifted and into a by compressed air or a jet of water Channel transported. A channel connects to the gutter, in which the dirt particles are removed. The cleaned Water leaves the drum screen through one or more Exhaust ducts. Two operating modes are possible: The Water can either cover the drum from the inside out or flow through from outside to inside. In the first case the dirt particles remain on the inside of the Hang the drum and in the second case on the outside.  

The known sieve drums consist of an axis as Storage, hereinafter referred to as the "central axle bearing" referred to, rotating around their bearing surfaces Drum casing and made of spokes as a connecting structure between the central axle bearing and the drum jacket. The drum is usually driven by a ring gear.

These drum screens have the disadvantage that the Spokes impede water flow. This means one increased flow resistance for the water and can in Extreme case due to dirt particles adhering to the spokes lead to a blockage of the sieve drum. Furthermore a good design of the central axle bearing is required and the spokes to withstand water pressure and stress Withstand dirt particles, leading to relatively high ones Lead costs for the screening drum leads.

The present invention is based on the object To improve flow resistance of a drum screen and to increase the mechanical resilience.

The object underlying the invention is thereby solved that rollers on the end faces of the screening drum are arranged, the axes of rotation parallel to the axis of rotation the screen drum, and which are in one move stationary annular side guide.  

The diameter of the sieve drum of drum sieves is larger than the width. Usually their diameter is at least twice their width. Is particularly preferred three to ten times the diameter. At the drum screen according to the invention is an operation with Flow direction of the water through the surface of possible inside out or outside in. The drum screen according to the invention has the advantage that there is no central axle bearing. It follows that the flow area of the water in the drum screen is none Construction elements, such as spokes, contains that hinder the flow of water. Also one Blockage of the screening drum caused by clogging Spoke gaps can arise here locked out. After all, there is a particular advantage justified that the rollers over the screening drum support their entire scope. Lead through it unforeseen high mechanical loads that lead to Example of a sudden increase in water pressure can occur, not to destroy the drum screen. The use of the sieve drum according to the invention is not limited to water filtration. Rather, you can all types of liquids are filtered.

According to a preferred embodiment of the invention, it is provided that the sieve drum consists of sieve elements,  which are arranged next to each other, and on which Sieve fabrics are attached.

The screen mesh is on the individual screen elements spanned. The screen mesh can be attached to the Example can be done by attached strips that with the Frame of the sieve element are screwed, the Sieve fabric is clamped between the frame and the last. It is advantageous if the sieve element with strip-shaped Reinforcing elements is provided. On this Reinforcing elements are on the screen and will supported against the incoming water.

A sieve drum made up of individual sieve elements has the advantage that in the event of damage by Exchange of individual sieve elements a repair can be carried out quickly and inexpensively.

According to a further preferred embodiment of the Invention it is provided that the width of the Sieve elements over the entire width of the sieve drum extends, and that each two adjacent screen elements the end faces movable via a connecting element are connected.

The movable connecting element can be advantageous Way out of a connecting plate and perpendicular to it Arranged tabs consist of two hinge pins are attached. About this perpendicular to the end faces  arranged hinge pins are the individual sieve elements flexibly guided.

A flexible connection between the individual Siebelementen has the advantage that unevenness in the stationary annular side guide can be compensated can without burdening the construction of the sieve drum.

According to a further preferred embodiment of the Invention it is provided that two on each screen element until six rollers are arranged.

By arranging several rollers on each Sieve element, the individual sieve element is stored stably. A number of four rollers is particularly preferred, each in the area of the corners of a screen element are arranged, which is a safe support of the Siebelements guaranteed. With a mobile Connection between the individual sieve elements is also at the same time a relatively large mobility of the Sieve elements enables.

According to a further preferred embodiment of the Invention it is provided that at least one over the entire circumference of the sieve drum extending Sprocket is arranged.

The ring gear can be placed inside the drum or a drive shaft arranged outside the sieve drum are driven. For operation with flow direction  of the water through the outer surface from the inside to the outside the arrangement outside, and vice versa The direction of flow is the arrangement within the Sieve drum preferred. This drives the Sieve drum always on the not with dirt particles loaded side of the drum shell.

This ensures a secure transmission of the Driving force and high reliability of operation.

According to a further embodiment of the invention, it is provided that two over the entire scope of the Sprockets extending sprockets are arranged, which consist of individual elements, each on the End faces of the screening drum are arranged.

This has the advantage that the sieve drum is driven can be done symmetrically and a one-sided load on the Sieve drum is avoided. The individual elements of the Sprockets are easily interchangeable if necessary.

According to a further preferred embodiment of the Invention it is provided that the stationary annular Lateral guidance from one with the surrounding building connected carrier and adjustably attached to the carrier there are annular guide rails that have a U-profile have, the opening parallel to the axis of rotation of the Casters is.  

The guide rails can for example Threaded bolts can be arranged adjustable. So one can Fine adjustment of the U-profile takes place, which creates a round The drum is guaranteed to run.

According to a further preferred embodiment of the Invention it is provided that the screening drum against the Environment on the stationary annular side guide is sealed by elastic sealing material.

The elastic seal can, for example, by a annular rubber sealing element made on the External surface of the U-profile is attached and over its entire scope extends.

This sealing material is used in an advantageous manner achieved that dirt particles are not already in that purified water.

According to a further embodiment of the invention, it is provided that on the connecting element between two adjacent sieve elements arranged a guide roller is that perpendicular to the face of a screen element is arranged, and the axis of which is perpendicular to the axis of rotation of the Rollers runs.

With the help of this guide roller, the screening drum is in advantageously in the direction of its axis against the Supported side guide and thus the distance of the Fixed castors for lateral guidance.  

According to a further embodiment of the invention, it is provided that the drive of the screening drum over a Gear transmission takes place.

A gear transmission ensures a safe and reliable transmission of the driving force.

According to a further preferred embodiment of the Invention it is provided that on one side of the Sieve drum is arranged a continuous channel that extends over the entire width of the screening drum, and that on the other hand he sieve drum one or more Nozzle tubes are arranged, the nozzle openings in Point in the direction of the gutter.

The gutter is on the side of the screen on the Drum shell adhering dirt particles arranged so that this, for example, by a jet of water from the the other side of the sieve drum arranged nozzle tube in the gutter be reeled. In the invention A continuous channel can not only be a drum screen outside the sieve drum - with a flow direction of the Water from the outside in - but also within the Sieve drum - with a water flow direction from inside out - to be arranged. A break the trough, as is the case with sieve drums with a central axle bearing is necessary to carry out the spokes. Therefore all the dirt collected in the gutter is removed by the Channel drained into the channel. The number of nozzle pipes is from the proportion and type of dirt particles. Is  their share is low and they are relatively easy from To remove screen mesh, a nozzle tube is sufficient. At high Proportion and relatively problematic removal are several To use nozzle pipes. This can be done by a few simple ones Experiments are identified.

According to a further embodiment of the invention, it is provided that transport blades on the sieve elements are arranged.

The transport blades consist, for example, of a along the edge of the screen element in the direction of Drum axis extending angularly curved Sheet with one leg attached to the screen element and the other leg perpendicular to the lateral surface of the Sieve drum or in a 45 ° maximum deviating angle in the direction of the incoming shows unpurified water. With the help of Large volume dirt particles get through through the transport scoop the rotation of the sieve drum upwards, that means from the Water, transported. All sieve elements or only some sieve elements, for example every second to fifth Siebelement, be equipped with a transport shovel. The optimal number and design of the Transport shovels is from the respective Operating conditions dependent and can be simple experiments can be determined.

The object of the invention is illustrated by the drawings explained in more detail.

Fig. 1 shows the drum screen in a perspective view.

Fig. 2 shows a section of the screen drum with the storage in the viewing direction parallel to the axis of rotation of the screen drum.

Fig. 3 shows a section of the screening drum with the storage in the viewing direction perpendicular to the axis of rotation of the screening drum.

Fig. 4 shows a section of the screen drum with the storage in the direction of view of the outer surface of the screen drum.

Fig. 5 shows a detail of the screening drum with the drive and the spray system for the removal of the dirt particles in the viewing direction parallel to the axis of rotation of the screen drum.

Fig. 6 shows a detail of the screening drum with the drive and the spray system for the removal of the dirt particles in the viewing direction on the casing surface of the sieve drum.

In FIG. 1, the drum screen is shown. The contaminated water passes through two inlet channels through inlet openings ( 1 ) on both sides into the inside of the sieve drum ( 2 ) - represented by the dark arrows - and flows out through the sieve mesh ( 3 ) of the immersed sieve elements ( 4 ) - represented by the white arrow - In an outlet channel located behind the screen fabric (not shown). This removes contaminants that are larger than the mesh size of the screen fabric ( 3 ). The screening drum ( 2 ) is driven by a drive ( 5 ) via two sprockets ( 6 ) and rotates about its axis of rotation (D1). The sieve drum ( 2 ) is supported and the forces resulting from a water level difference are introduced directly from the sieve elements ( 4 ) via rollers ( 7 ) and ring-shaped side guides ( 8 ), which are anchored in the structure.

In Fig. 2, the screening drum ( 2 ) is shown in a section in which a movable connection between two adjacent screen elements ( 4 ) and their storage via rollers ( 7 ) is shown. The rollers ( 7 ) are each arranged at the corners of the screen elements ( 4 ). The sieve elements ( 4 ) are movably connected to one another via pivot bolts ( 10 ) by connecting elements ( 9 ). The screening drum ( 2 ) is supported against the side guide ( 8 ) by means of guide rollers ( 11 ). Individual gear ring segments ( 12 ) are attached to the end faces of the sieve elements ( 4 ), from which the gear rings ( 6 ) are composed. Transport blades ( 13 ) are attached to the sieve elements ( 4 ). All or only some of the sieve elements ( 4 ) can be equipped with transport blades ( 13 ).

In Fig. 3 is a vertical section is shown by the results shown in Fig. 2 section of the sieve drum (2). The ring-shaped side guides ( 8 ) for the rollers ( 7 ), which rotate about their axis of rotation (D2), consist of a U-rail ( 14 ) which is screwed to anchor plates ( 16 ) via threaded bolts ( 15 ). The anchor plates ( 16 ) are concreted into the structure in a ring at a uniform distance. The U-rail ( 14 ) is adjusted via the threaded bolts ( 15 ). The ring gear segments ( 12 ) are screwed to the end face of the sieve elements ( 4 ). The screen fabric ( 3 ) is stretched flat on the screen element ( 4 ). The sieve drum ( 2 ) is sealed by an annular rubber sealing element ( 17 ).

In Fig. 4, the screening drum ( 2 ) is shown in a detail, in which a movable connection between two adjacent sieve elements ( 4 ) and their storage via rollers ( 7 ) is shown in a plan view of the outer surface. The sieve elements ( 4 ) are movably connected to one another via connecting elements ( 9 ). They are supported by rollers ( 7 ) and supported and supported by guide rollers ( 11 ) on the annular side guide, which consists of a U-rail ( 14 ), threaded bolts ( 15 ) and anchor plates ( 16 ).

In FIG. 5, the drive (5) is shown the screen drum (2) and a spray system for discharging the dirt particles in the viewing direction parallel to the axis of rotation (D1) of the sieve drum (2). The screening drum ( 2 ) is driven by a motor ( 18 ) via two toothed wheels ( 19 ) and two toothed rings ( 6 ). The drive ( 5 ) is provided with a protective hood ( 20 ). The dirt particles accumulating on the inside of the sieve drum ( 2 ) are blown into a channel ( 23 ) through two nozzle pipes ( 21 ), which are covered with a hood ( 22 ). A transport blade ( 13 ) is attached to every third screen element ( 4 ).

In FIG. 6, the drive (5) is shown the screen drum (2) and a spray system for discharging the dirt particles in the viewing direction on the casing surface of the sieve drum (2). The drive ( 5 ) of the screening drum ( 2 ) via the motor ( 18 ), two gear wheels ( 19 ) and the two ring gears ( 6 ) is arranged at the highest point of the screening drum ( 2 ). The protective hood ( 20 ) extends over the entire width of the screening drum ( 2 ). The nozzle tubes ( 21 ), their hood ( 22 ) and the channel ( 23 ) extend over the entire width of the screening drum ( 2 ).

The invention will now be described with reference to an example explained.

The drum screen is constructed as shown in FIGS. 1 to 6. The width of the sieve drum is 2 m and its diameter is 10 to 14 m. Structural steel (R St 37-2) is used as the material for the frame of the screen elements and the side guide. The face plates of the sieve elements, the sieve mesh, the bolts for mounting the rollers and the sprockets of the drive are made of stainless steel. The guide rollers are made of hardened stainless steel. Plastics, such as PA, are used for rollers and sprocket segments. It is driven by a spur gear motor in a cast iron housing with a drive power of 3.0 to 4.4 kW. The sieve drum is operated at a peripheral speed of 6 cm / s to 24 cm / s. With a mesh size of 4 mm and an average accumulation difference of 0.5 m water column, the water throughput is approx. 20,000 m³ / h. The sieve drum drive is regulated with the aid of a level control, which records the value of the water level difference between the upstream and downstream sides of the drum screen. If the water level difference reaches a previously set value, the sieve drum drive is first switched on at a relatively slow speed, for example at 6 cm / s. If the water level difference continues to increase, the sieve drum drive switches to a higher speed of, for example, 12 cm / s. In the event of extreme contamination and if the water level difference increases further, the drive takes place at a relatively high speed, for example at 24 cm / s. If the screen fabric has been cleaned by the spray device to such an extent that the water level difference has decreased again, the drive of the screen drum is switched off. A trailing device, however, leaves the sieve drum in operation until the final standstill so that all sieve elements are completely cleaned by the spray device. If the level control does not give any impulse to switch on the drive for a longer period of time, the drive of the sieve drum is automatically switched on in order to prevent contaminants from becoming lodged and encrusted on the sieve mesh.

Claims (12)

1. Drum screen with a larger diameter than the width of the outer surface of the screening drum ( 2 ), characterized in that rollers ( 7 ) are arranged on the end faces of the screening drum ( 2 ), the axes of rotation (D2) of which are parallel to the axis of rotation (D1) Sieve drum ( 2 ) run, and which move in a stationary annular side guide ( 8 ). 2. Drum sieve according to claim 1, characterized in that the sieve drum ( 2 ) consists of sieve elements ( 4 ) which are arranged adjacent to one another, and on which sieve cloth ( 3 ) are attached. 3. Drum sieve according to claim 1 or 2, characterized in that the width of the sieve elements ( 4 ) extends over the entire width of the sieve drum ( 2 ), and that two adjacent sieve elements ( 4 ) on the end faces via a connecting element ( 9 ) are movably connected. 4. Drum screen according to one of claims 1 to 3, characterized in that two to six rollers ( 7 ) are arranged on each screen element ( 4 ). 5. Drum screen according to one of claims 1 to 4, characterized in that at least one toothed ring ( 6 ) extending over the entire circumference of the screening drum ( 2 ) is arranged. 6. Drum screen according to claim 5, characterized in that two toothed rings ( 6 ) extending over the entire circumference of the screening drum ( 2 ) are arranged, which consist of individual elements ( 12 ), each arranged on the end faces of the screening drum ( 2 ) are. 7. Drum screen according to one of claims 1 to 6, characterized in that the stationary annular side guide ( 8 ) consists of a carrier connected to the surrounding structure ( 16 ) and adjustable on the carrier mounted annular guide rails ( 14 ) which have a U-profile have, the opening of which is parallel to the axis of rotation (D2) of the rollers ( 7 ). 8. Drum sieve according to one of claims 1 to 7, characterized in that the sieve drum ( 2 ) is sealed against the environment on the stationary annular side guide ( 8 ) by elastic sealing material ( 17 ). 9. Drum screen according to one of claims 3 to 8, characterized in that on the connecting element ( 9 ) between two adjacent screen elements ( 4 ) a guide roller ( 11 ) is arranged, which is arranged perpendicular to the end face of a screen element ( 4 ), and the Axis perpendicular to the axis of rotation (D2) of the rollers ( 7 ). 10. Drum screen according to one of claims 5 to 9, characterized in that the drive of the screen drum ( 2 ) via a gear transmission ( 5 ). 11. Drum screen according to one of claims 1 to 10, characterized in that a continuous channel ( 23 ) is arranged on one side of the screen drum ( 2 ), which extends over the entire width of the screen drum ( 2 ), and that on the On the other side of the screening drum ( 2 ) one or more nozzle tubes ( 21 ) are arranged, the nozzle openings of which point in the direction of the channel ( 23 ). 12. Drum screen according to one of claims 2 to 11, characterized in that transport blades ( 13 ) are arranged on the screen elements ( 4 ).