RU103740U1 - DRAINAGE AND DISTRIBUTION DEVICE - Google Patents

Abstract

 1. A drainage distribution device containing a collector, distribution pipes connected to it, made perforated along the forming surface with plugs at the ends of the pipes, and slotted filter elements located at a distance relative to each other along the length of the distribution pipes, characterized in that the slotted filter - the elements are located directly on the distribution pipes made with threads at the locations of the filter elements along the length of the distribution pipes and perforations made in the form of Hezey located on the upper forming surface of the pipes. ! 2. The drainage distribution device according to claim 1, characterized in that the slotted filter elements are made in the form of a wire wound directly on the sections of the distribution pipes made with thread and slots, or made in the form of a wire wound directly on individual threads made and slotted distribution tubes interconnected by means of cylindrical inserts into a single block of distribution pipes.

Description

The proposed utility model relates to the purification of liquids by filtration through bulk materials and can be used for all types of filters of chemical water treatment systems in the energy sector and other industries. In particular, the proposed drainage distribution device (DRU) is intended for ion exchanger filters of water treatment plants of boiler plants, heating plants, chemical and other industries where it becomes necessary to purify water and other liquids. A drainage distribution device is used to distribute both rinsing and filtered water over the filter area.

It is known DRU made in the form of a series of parallel-laid slotted tubes that are placed in the thickness of the filter media at a depth of 500-600 mm from the surface of the filter load. Slots in the pipes are parallel to the longitudinal axis of the pipe and directed downward. The number of drainage pipes and the distance between them is determined by calculation, depending on the diameter of the pipes. The ratio of the area of the slots of the drainage pipes (counting along the inner surface of the pipe) to the filter loading area should be 1.5-2.0%. The bulk of the water is filtered from bottom to top. Water passes first a coarse load, and then a smaller load. As a result, the suspended suspended particles are more evenly distributed in the thickness of the filter load. The filter space above the load is communicated by a pipeline with a pan. After filling the filter with water from above, part of the source water enters the switchgear through the shallow load layer, and the other part through the pipeline goes into the pallet space and, filtered from the bottom up, through the layer of the larger load is also sent to the switchgear. The flow rates of water moving in both directions vary depending on the ratio of hydraulic resistances. Since the dirt capacity of the upper layer is small, the flow rate of the water passing here will gradually decrease due to the deposition of contaminants in the shallow charge. The flow rate of water passing through the bottom layer will increase. Thus, the balance of the friction forces acting on the load is maintained, and the load remains in a monolithic state. By the end of the working cycle of the fast two-line filter, the amount of water coming from below reaches 80% of its total amount. Pure water is collected from the slotted pipes of the DRU and discharged from the filter through the filtering speed controller.

The DRU is flushed with flushing water at a speed of not more than 2 m / s and a flow rate of flushing water through the slits of 0.8 m / s, which corresponds to the recommended rate of blowing through the slots, which is necessary to eliminate jamming of the slots with particles of a fine filter load stuck in them. (B. F. Kozhinov, Purification of Drinking and Industrial Water, Publishing House of Literature on Construction, M., 1971, pp. 162-163, 167-169).

The known DRU is characterized by a loss of pressure in the drain due to jamming of the slots by the particles of the fine filter load stuck in them, which makes it necessary to intensify the washing of the DRU, increases the flow rate of the wash water, the duration of the wash, and, ultimately, reduces the filter performance.

It is also known DRU, made in the form of a collector with outlet pipes fixed to it, equipped with slotted filter elements. On the branch pipes, nipples are welded onto which slotted filter elements are screwed in the form of drainage slotted caps - porcelain or plastic. On the outer surface of the caps there are slots 0.3-0.5 mm wide. The design of the switchgear ensures uniform distribution of compressed air, which eliminates the need for a separate air distribution system to flush the device (V.F. Kozhinov, Purification of drinking and industrial water, Building Literature Publishing House, M., 1971, pp. 179-180).

A disadvantage of the known device is the complexity and increased cost of the design of the switchgear, due to the cost of filter elements — slotted caps made of porcelain, which are more resistant to abrasion by a large loading of the material when washing the filter compared to plastic caps — cheaper in price, but less resistant to abrasion compared to china.

In addition, this design of the differential switchgear also does not exclude the possibility of jamming of the slots of the filter element by the particles of the fine filter load stuck in them.

It is also known DRU containing a collector and beam slotted filter elements made of wire wound on frames with plugs at the ends. Slotted filter elements completely cover the surface of the frames and are made of a triangular cross-section wire wound on the frames. The sizes of the slots can be from 0.1 to 0.8 mm. (Email: Agroten@ukr.net WWW: \\ agroten: odessa.net.).

The known design does not provide uniform distribution of fluid flow along the diameter of the filter. This is due to a decrease in water pressure at the end sections of the slotted filter elements and does not contribute to eliminating jamming of the filter element slots by particles of a fine filter load stuck in them. In addition, the location of the slots of the filter elements along the entire forming surface of the frames causes an increase in the total area of the passage section of the fluid flow from the filter elements compared to the area of the passage section of the fluid inlet into the distribution pipes.

The closest in technical essence and the achieved result is a drainage distribution device containing a collector, distribution pipes connected to it, made perforated along the forming surface with plugs at the ends of the pipes, and slotted filter elements located at a certain distance relative to each other along the length of the distribution pipes .

Distribution pipes are made of plastic, the perforation of the pipes is made in the form of ellipses and is located along the entire forming surface of the pipes. Slotted filter elements are made in the form of cylinders located with a certain clearance on perforated distribution pipes. (Patent RU 87907 U1, publ. 09/27/2009)

The known device is characterized by significant losses of fluid pressure due to the formation of fluid "pockets" in the gaps between the filter elements and sections of the distribution pipes on which the filter elements are located and fixed. In addition, the device does not provide for the formation of a jet of fluid flow in the required direction and does not help to eliminate jamming of the slots of the filter elements by particles of fine filter loading stuck in them due to the location on the perforation pipes over the entire forming surface, which disperses the fluid flow jet through 360 °.

The utility model is based on the task of improving the design of the known DRU, in which by means of a new arrangement and execution of known elements, as well as a new interaction of these elements with each other, it is possible to form a jet of a liquid stream in the necessary direction, to reduce the loss of pressure head of the liquid stream along the filter diameter and reduce the possibility of jamming of the slots of the filter elements stuck in them with particles of a small filter load.

The problem is solved in that in a known drainage distribution device containing a collector, distribution pipes connected to it, made perforated along the forming surface with plugs at the ends of the pipes, and slotted filter elements located at a certain distance relative to each other along the length of the distribution pipes, according to the proposed utility model, slotted filter elements are located directly on the distribution pipes made with thread at the locations of the filter elements along the length of the distribution pipes, and perforations made in the form of slots located on the upper forming surface of the pipes.

The problem is also solved by the fact that slotted filter elements are made in the form of a wire wound directly on the sections of perforated distribution pipes made with threads and slots, or are made in the form of a wire wound directly on the separate distribution pipes made with threads and slots connected between by means of cylindrical inserts into a single block of radiation distribution pipes.

Making cuts only along the upper forming surface of the pipes ensures the formation of a jet plume with a sweep angle of 90 to 240 ° in the upper circular sector of the distribution pipes and slotted filter elements, which leads to the concentration of the direction of the jet plume in the required direction on certain sections of the distribution pipes, increasing the pressure of the fluid flow passing both through the slots of the distribution pipes and through the slots of the filter elements, thereby reducing the possibility of jamming of the filter slots p-element fine particles of filter media. The location of the slotted filter elements directly on the distribution pipes eliminates the formation of liquid "pockets" thus providing a reduction in the pressure loss of the liquid passing through the distribution pipes and filter elements. In this case, the cross-sectional area of the fluid flow through the slotted filter elements becomes less than or equal to the cross-sectional area of the fluid inlet to the distribution pipes.

The technical result of the proposed utility model is to provide the possibility of forming a jet stream of a liquid stream in the required direction, reducing the loss of pressure of the liquid stream along the diameter of the filter and reducing the possibility of jamming of the slots of the filter element with particles of a fine filter load.

The proposed DRU contains a collector, distribution pipes connected to it, made with plugs at the ends of the pipes and slotted filter elements located directly on the distribution pipes at a certain distance from each other along the length of the distribution pipes. Distribution pipes are made with slots located on the upper forming surface of the pipes, and a thread located at a certain distance relative to each other (certain areas) along the length of the distribution pipes at the locations of the slotted filter elements.

Slotted filter elements can be made in the form of a wire, wound in a hot state directly on sections of distribution pipes made with threads and slots, or made in the form of a wire, wound in a hot state directly on separate, made with threads and slots of distribution pipes, connected between by means of cylindrical inserts into a single block of distribution pipes ..

The axial distances between the sections of the distribution pipes with slotted filter elements or individual distribution pipes with slotted filter elements and the number of slotted filter elements are calculated depending on the diameter of the filter and the outer diameter of the distribution pipes. The sizes of the slots can be from 0.1 to 0.8 mm.

The thread pitch, wire diameter and the number of slots determine the filter performance and the distribution of fluid flows. The proposed utility model is illustrated in the drawing, Figs. 1, 2, 3. Fig. 1 shows a DRU in section, including: a collector 1, distribution pipes 2 connected to it with plugs 3 at the ends, slotted filter elements 4 located at a certain distance relative to each other along the length of the distribution pipes 2.

Figure 2, shows the distribution pipe 2, made with a thread 5 and slots 6 located on the upper forming surface of the pipe 2.

Figure 3 shows a fragment of the slotted filter element 4, made in the form of a wire 7, wound on sections of the distribution pipes 2, made with thread 5 and slots 6. In addition, figure 1 shows the filter housing 8, and mounts 9 with which DRU is mounted in the filter housing 8. In figure 3. shown mounting 10 with which slotted filter elements 4 are mounted on the distribution pipes 2.

The proposed DRU works as follows. The source water enters the filter in two streams: through one pipe and troughs to the top of the filter, and through two other pipelines through the collector 1, distribution pipes 2 with slotted filter elements 4 in the switchgear mounted on the bottom of the filter in the upper and lower parts . Pure water is collected by the DRU from the slotted filter elements 4 and is discharged from the filter through the filtering speed controller. At the same time, the valves regulating the water inlet to the upper part of the filter through the channels, the entrance to the lower switchgear and the outlet of clean water from the upper filter divider are open. When washing a two-line filter, these valves close and open the valves on the pipeline for supplying washing water to the upper switchgear and exit it into the gutters. Rinsing water with an intensity of 6-8 l / s per 1 m ² first enters the upper switchgear for 1-2 minutes. A subsurface flushing occurs, loosening the over-drainage layer of sand. The gutters collect contaminated water and take it to a side pocket behind the filter wall, from where it goes to the drain. Then the gate valve of the wash water inlet to the lower switchgear is opened and thus the main lower flush is activated with an intensity of 13-15 l / s per 1 m ² . Within 5-6 minutes, the wash water enters the lower switchgear. At the same time, wash water is supplied to the drainage system with a minimum intensity in order to create backpressure in the drainage, which prevents the penetration of contaminants washed out of the lower layers of the charge into the filtrate. After the main bottom flushing is completed, the valve at the inlet of the flushing water in the lower switchgear is closed and flushing water with an intensity of 10-12 l / s per 1 m ^{2 is} fed into the drain for 1-2 minutes to purge the slotted filter elements 4.

Claims (2)

1. A drainage distribution device containing a collector, distribution pipes connected to it, made perforated along the forming surface with plugs at the ends of the pipes, and slotted filter elements located at a distance relative to each other along the length of the distribution pipes, characterized in that the slotted filter - the elements are located directly on the distribution pipes made with threads at the locations of the filter elements along the length of the distribution pipes and perforations made in the form of Hezey located on the upper forming surface of the pipes. 2. The drainage distribution device according to claim 1, characterized in that the slotted filter elements are made in the form of a wire wound directly on the sections of the distribution pipes made with thread and slots, or made in the form of a wire wound directly on individual threads made and slotted distribution tubes interconnected by means of cylindrical inserts into a single block of distribution pipes.