CZ2470U1 - Reactor of wastewater treatment plant - Google Patents

Description

Technical field

The technical solution relates to chemical waste water treatment plants, namely their reactors consisting of a mixing space, a sedimentation space with sludge removal, a floating filtration layer filter space and a filtered water supply space. ..

Background Art

The reactors of chemical waste water treatment plants are known, whose interior space is divided into various mixing, sedimentation and filtration spaces by means of various built-in units, which use a floating filter layer above which there is a filtered water storage space, which is used for washing the filter capacity. This includes a reactor, which is the subject of CSA 238701. This reactor has a rectangular plan, a sludge draw-off at the bottom, which narrows in a pyramid shape. The interior of the reactor is basically divided into five sub-compartments - rapid mixing, slow stirring, sludge, sedimentation and ultimately the filtered water space. These spaces are separated by various built-in fittings that also regulate the passage of purified water through the reactor.

A disadvantage of the known reactors of the described type is their considerable internal rupture, their construction does not allow the cleaning efficiency to be maintained in their miniaturization.

The technical solution therefore aims to create a reactor for chemical waste water treatment plants, which allows the plant to adopt a minimum floor area while maintaining high efficiency. ,

The essence of the technical solution

This task is solved by a reactor of a sewage treatment plant consisting of a mixing space, a sedimentation area with sludge removal, a filtering space with a floating filtration layer and a filtered water storage space, which consists in a substantially cylindrical vessel with a vertical axis, the bottom part is reduced to a cone with a sludge exhaust, in which a hollow cylindrical installation is suspended, which is partially filled with a layer of granulated filter material lighter than water and has an inner space separated by a sieve from the filtered water supply space, the raw water inlet being at the top of the space between the cylindrical vessel and the installation.

The feed of the raw water to the reactor is preferably made tangentially, the sludge withdrawal is guided by an ascending pipe with a sludge pump to overflow above the level of filtered water, the overflow being connected to the ambient atmosphere. The lower end of the recess tapered and is preferably provided with an expanding neck to enhance the centrifugal effect to separate the sludge

In a preferred embodiment, the volume of the filtered water storage space is increased such that its surface area is larger than the planar surface of the cylindrical container and the storage space extends in one direction outside the cylindrical container, the projection width being smaller than the diameter of the cylindrical container.

This layout allows you to concentrate large cleaning performance on a small floor area of the plant.

Figures in the drawing

The invention will now be further elucidated with reference to the drawing, in which: Figure 1 is a vertical sectional view of the reactor DD as well as the entire plant of Figure 2; Figures 2 to 4 are horizontal sectional views of the reactor, and AA, BB and CC plants of Figure 1; Fig. 5 is a front view R in Fig. 6; Fig. 6 is a view P of Fig. 5 of a treatment plant without a top cover, and Fig. 7 is a view Q of Fig. 5 below a side cover of the treatment plant.

Example of execution

The reactor is a substantial part of the wastewater treatment plant. It is formed by a cylindrical vessel 1 with a vertical axis, which is underneath reduced to a cone 2 and extends in a top direction in one direction in the upper part which defines the storage space 3 of the filtered water. Below the storage space 3, a hollow cylindrical housing 4, which has a reduced diameter at the lower end and is terminated by a neck 5, is coaxially suspended in the vessel 1. The internal space of the installation 4 is separated from the storage space 2 by a sieve 6 which has the purpose of maintaining a layer 7 of granulated filtration lighter than water, e.g., polystyrene granules. In the upper part of the vessel 1 below the storage space 3 there is a tangentially directed raw water inlet 8, the sludge exhaust 9 is at the lowest point of the cone 2 together with the wash water outlet 10. The effluent 11 of the filtered water from the reactor is in the bottom of the storage space.

The function of the entire treatment plant will be described below to clarify the reactor's function: Crude water is pumped to the treatment plant by pumps 12 from the sludge pit, where it has been rid of the coarsest impurities. The dosing pumps 13 feed the flocculant into the raw water stream. They are mixed with water in a mixing 14 provided with turbulence inducing inlets in the water stream. The raw water mixed with the flocculants flows into the reactor through the inlet 8, whose tangential inlet brings the container 1 charge into a rotational motion which promotes further mixing of the water with the flocculant and contributes in the space of the cone 2 to a centrifugal effect to divide the flakes. Sludge flakes, due to the reduction in water velocity in the cone space, sit on its bottom. The sludge is discharged by the exhaust 9 in the shear, rises through the sludge pump tube 15 to overflow 16 above the level 17 in the reactor and from there falls into the sump. The overflow 16 is connected to the ambient atmosphere through the opening 18 to prevent possible spontaneous emptying of the reactor. At the same time, the wash water outlet 10 is drained at the outlet 9.

From the offset space in the cone 2, the settled water passes into the built-in space 4, where it passes through the filter layer 2 of the polystyrene granules and the sieve 6 into the storage space 3. · The volume of the storage space 3 is expanded in one direction above the space in which the additional treatment plant equipment is located. in this case, the width of this extension is chosen such that it leaves on the one hand free space for the overflow 16 and the wash controller 19 and on the other hand a space for the carbon filter 20 of the purified water. From the bottom of the storage space 2, the filtered water is discharged via the drain 11 to the carbon filter 20, and from there the outlet 21 of the treatment plant can then be led, e.g. When the treatment plant is installed, for example in a closed circuit of a washing line, the carbon filter 20 can be drained.

Reactor resp. the treatment plant with the described reactor can be used especially for lines and boxes for washing cars, in water treatment plants at swimming pools and the like.

Claims (6)

Claims for PROTECTION Wastewater treatment plant reactor comprising a mixing space, a sedimentation space with a sludge withdrawal, a filtration space with a floating filter layer and a filtered water storage space, characterized in that it consists of a substantially cylindrical vessel (1) with a vertical axis, in a lower part reduced to a cone (2) with a sludge withdrawal (9) in which a hollow cylindrical insert (4) is suspended, which is partially filled with a layer (7) of granulated filter material lighter than water and having an inner space top separated by a sieve (6) from the filtered water storage space (3), the raw water inlet (8) being at the top of the space between the cylindrical vessel (1) and the installation (4). Reactor according to claim 1, characterized in that the raw water inlet (8) is designed tangentially. Reactor according to claim 1, characterized in that the sludge withdrawal (9) is led through an ascending pipe (15) to the overflow (16) above the level of the filtered water (17), the overflow (16) _t being connected to the ambient atmosphere. . Reactor according to claim 1, characterized in that the lower end of the installation (4) tapers conically and is provided with an expanding throat (5). Reactor according to claim 1, characterized in that the surface area of the storage space (3) is larger than the surface area of the cylindrical vessel (1). Reactor according to claim 5, characterized in that the supply space (3) extends in one direction outside the plan view of the cylindrical vessel (1), the projection width being smaller than the diameter of the vessel (1).