RU175457U1 - Vertical inertial gravity filter - Google Patents

Abstract

The utility model relates to devices designed for water purification, and can be used to filter the water of heating networks, thermal power plants, boiler houses and industrial enterprises. The technical result aimed at achieving this utility model is to increase the efficiency of liquid purification in a vertical inertial-gravity filter The essence of the utility model lies in the fact that the vertical inertial-gravity filter contains a housing with an inlet and outlet of liquid, inside of which there is a A filter column containing perforation areas covered by conical visors installed with large bases down is married. In contrast to the prototype, the diameter of the larger base of each conical visor exceeds the diameter of the large bases of the conical visors mounted above it. 5 C.p. f-ls, 1 fig.

Description

The utility model relates to devices designed for water treatment, and can be used to filter the water of heating networks, thermal power plants, boiler houses and industrial enterprises.

Known vertical inertial-gravity filter, which contains a hollow cylindrical body equipped with inlet and outlet nozzles, inside of which is located a closed top pipe connected to the outlet nozzle. In this case, the side surface of the pipe contains slits covered by curved visors with the same base diameter. [RU No. 65784, priority date 1/16/2007, publication date: 8/27/2007, IPC: B01D 43/00].

Known vertical inertial-gravity filter containing a hollow body, equipped with inlet and outlet pipes, inside which there is a vertical pipe, the upper part of which is equipped with a conical fairing. Moreover, the lateral surface of the vertical pipe contains longitudinal slots covered with conical visors with cylindrical skirts. Moreover, the visors have the same base diameter [RU No. 54318, priority date: January 10, 2006, publication date: June 27, 2006, IPC: B01D 43/00].

As a prototype, a vertical inertial-gravity filter was chosen, consisting of a hollow cylindrical body equipped with liquid inlet and outlet, and a filtering cylindrical column located inside it, containing holes on the side surface covered with conical visors installed with large bases downward. In this case, the large bases of the conical visors have the same diameter [RU No. 2504711, priority date: 12.24.2012, publication date: 01.20.2014, IPC: F16L 55/24].

The disadvantage of the prototype is the low efficiency of liquid purification due to the design of the conical visors, in particular the fact that they have the same diameter of large bases, which reduces the effect of the second and subsequent conical visors on the fluid flow, as a result, reducing the inertial component of the force that separates the particles of contaminants from the stream liquids, worsening the performance of a vertical inertial-gravity filter.

The technical problem to which the utility model is directed is to increase the operational characteristics of a vertical inertial-gravity filter.

The technical result, which the utility model aims to achieve, is to increase the efficiency of liquid purification in a vertical inertial-gravity filter.

The essence of the claimed utility model is as follows.

The vertical inertial-gravity filter contains a housing with liquid inlet and outlet, inside of which there is a filter column containing perforation areas covered with conical visors installed with large bases downward. In contrast to the prototype, the diameter of the larger base of each conical visor exceeds the diameter of the large bases of the conical visors mounted above it.

Increasing the diameter of the larger base of each subsequent conical visor provides an opportunity to increase the surface area of the conical visors affecting the fluid flow. An increase in the diameter of the larger base of each conical visor can be realized either by changing the height of the conical visor, or by changing the angle of inclination of the side surface of the conical visor, or by a combination of these methods. Moreover, the choice of the method can be based on the optimal ratio between performance and compactness and determined by the technical requirements for a vertical inertial-gravity filter.

The fluid inlet is designed to supply fluid to the upper surface of the filter column. The fluid outlet is designed to withdraw fluid from the filter column. The inlet and outlet of the liquid can be represented by pipes, nozzles, holes or other structural elements.

The filter column is located inside the housing, has a hollow structure and can have any shape and size. The upper surface of the filter column may have a streamlined shape or may be equipped with a cowl, for example, conical, spherical or otherwise, providing a decrease in hydraulic resistance due to shockless flow around the upper surface of the filter column. The filter column can be installed coaxially with the inlet and outlet of the liquid, which ensures uniform distribution of the liquid inside the vertical inertial-gravity filter, positively affecting its performance and hydraulic resistance.

The filter column on the side surface contains perforation areas that allow fluid to pass through. The perforation areas may contain a different number of holes, which may have a different shape and size, which makes it possible to change the throughput of the perforation areas. The perforation areas can be covered with nets, filters or contain other devices that provide the ability to capture small particles and increase the degree of purification of the liquid.

The housing is a hollow sealed structure and may have a cylindrical or other shape. The upper part of the housing may contain fittings or tubes designed to remove volatile compounds and pop-up contaminants. The lower part of the housing may contain fittings or tubes designed to remove particles of impurities deposited on the bottom. The side surface of the housing may contain a sealed hatch designed for cleaning and inspection of the housing from the inside.

Additionally, to reduce the risk of lifting particles of impurities from the bottom of the vertical inertial-gravity filter, the housing in the lower part may contain a chipper. The chipper can be represented by an inverted truncated cone, spherical or other surfaces.

Additionally, to increase the compactness of the vertical inertial-gravity filter, the conical visors can be arranged so that the upper part of one conical visor is in the region of the column covered by the previous conical visor.

Additionally, to increase the structural rigidity of the vertical inertial-gravity filter, the filter column may have additional attachment points to the inner surface of the housing. In this case, the fastening of the filter column can be carried out by means of rods, extensions or other known methods.

The details of the vertical inertial-gravity filter can be made of metal, for example, steel, aluminum, cast iron or other known materials, and can be connected by any detachable or one-piece methods, for example by means of a threaded connection, welding, riveting or other known methods.

The utility model possesses a combination of essential features previously unknown from the prior art, characterized in that the diameter of the larger base of each conical visor is larger than the diameter of the large bases of the conical visors installed above it, which provides an increase in the contact area of each subsequent conical visor with the fluid flow, contributing to intensive flow deflection fluid to the periphery of the housing, increasing the speed of the vortex movement in the region of the edges of the conical visors and, accordingly, in the impact of inertia forces separating the polluting particles from the fluid flow, thus allowing to achieve a technical result, which consists in increasing the efficiency of liquid purification, thereby increasing the operational characteristics of the vertical inertial-gravity filter.

The presence of new distinctive essential features indicates the compliance of the utility model with the patentability criterion of “novelty”.

The utility model can be made of known materials using known means, which indicates the compliance of the utility model with the patentability criterion of "industrial applicability".

The utility model is illustrated by the following drawings.

FIG. 1 - vertical inertial-gravity filter, General view.

The vertical inertial-gravity filter contains a housing 1, equipped with an inlet pipe 2, an outlet pipe 3, volatility removal fittings 4, impurity particle removal fittings 5 and airtight manholes 6. A filter column 7 is located inside the housing 1 and is connected to the outlet pipe 3, side surface which contains areas 8, 9, 10 of perforation, equipped with filters 11 and covered with conical visors 12, 13 and 14 with a successively increasing diameter of large bases. When this filter column 7 is equipped with a spherical fairing 15, and inside the housing in the lower part is located fender 16.

The utility model works as follows.

The vertical inertial-gravity filter is connected through the inlet and outlet pipes 2, 3 to the pipelines for supplying and discharging liquid. The fluid flow enters the housing 1 through the inlet pipe 2 and dissecting about the spherical fairing 15, passes along the surface of the conical visor 12 and deviates radially to the periphery of the housing 1. After passing the edge of the larger base of the conical visor 12, part of the fluid flow unfolds under the conical visor 12 and sent towards the perforation region 8. Under the action of inertia forces, part of the impurities separates and moves down when the fluid flow turns, and part of the impurities is deposited on the filter 11. The fluid flow continues to move down and interacts with the surfaces of the conical visors 13 and 14. In this case, the fluid flow deviates many times to the periphery of the housing 1 and turns around under the conical visors 13 and 14 to the perforation regions 9 and 10, and the impurity particles continue to separate. The fluid flow flows through the perforation region 8, 9, 10 into the filter column 7 and moves through the outlet pipe 3 outward from the vertical inertial-gravity filter. In this case, volatile compounds and light suspensions rise up and are removed through nozzles 4, and particles of impurities under the influence of gravity move down and fall on the baffle plate 16. Particles of impurities roll down the baffle plate 16 to the lower part of the housing 1 and are discharged through the nozzles 5 to remove particles impurities. At the same time, the baffle plate 16 prevents the particles of impurities from rising from the fluid flows from the bottom of the housing 1. When the vertical inertial-gravity filter is clogged, the airtight hatches 6 are opened and cleaned.

Thus, a technical result is achieved, which consists in increasing the efficiency of cleaning the fluid flow, and thereby increase the operational characteristics of the vertical inertial-gravity filter.

Claims (6)

1. A vertical inertial-gravity filter containing a housing with liquid inlet and outlet, inside which there is a filter column containing perforation regions covered with conical visors installed with large bases downward, characterized in that the diameter of the larger base of each conical visor exceeds the diameter of the large conical bases visors mounted above it. 2. The vertical inertial-gravity filter according to claim 1, characterized in that the vertical cylindrical column on top is provided with a spherical fairing. 3. The vertical inertial-gravity filter according to claim 1, characterized in that the perforation areas are covered with nets. 4. The vertical inertial-gravity filter according to claim 1, characterized in that the upper part of each subsequent conical visor is located in the column area covered by the previous conical visor. 5. The vertical inertial-gravity filter according to claim 1, characterized in that it contains a chipper located in the lower part of the housing. 6. The vertical inertial-gravity filter according to claim 1, characterized in that the filter column contains attachment points to the inner surface of the housing.

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