RU64097U1 - SUMP - Google Patents

Abstract

The mud sump is designed to eliminate mechanical impurities in the form of suspended particles from the inlet-dispersion medium transported through the pipeline, in particular, it can be used in water circulation systems, in the heat engineering equipment of boiler houses, heating networks, central heating centers and heating centers of buildings. When using it, an increase in the efficiency of cleaning the medium is achieved due to more efficient removal of light fractions of contaminants. Cleaning the sump itself does not require disassembling - the dirt flows out of it through a special pipe. The sump includes a housing 1, on one axis of which an inlet 2 and an outlet 3 nozzles are installed. A pipe 4 is mounted on the same axis in the housing and is rigidly connected to the outlet pipe 3. On the inlet pipe 2 side, the pipe 4 is closed by a fenders, water-guiding surface 5, the shape of which allows water to slide along it toward the bottom. Around the pipe 4, along it, water-guiding surfaces are installed 6. On the parts of the pipe, overlapped by the water-guiding surfaces, longitudinal slots are made 8. The bottom 10 of the body can be made conical, or it can be flat. The output end of the inlet pipe 2 is recessed into the inside of the housing, and its edge expands towards the bottom. The expanding end of the inlet nozzle separates the upper chamber in the mud casing, in which light fractions of impurities floating up in the water accumulate, which are removed through the nozzles 13.

Description

The utility model is designed to remove mechanical impurities from the water-dispersion medium transported through the pipeline, including in the form of suspended particles, in particular, can be used in water circulation systems, in the heating equipment of boiler houses, heating networks, central heating centers and heating centers of buildings.

It is known to use for purification of water flowing through a pipeline, a magnetic-mesh mud collector (RU Patent No. 2193539). The device consists of a cleaning housing, in which pipes made of non-magnetic material are installed in the horizontal direction. There are magnets in the pipes that attract the sludge. The disadvantage of a magnetic grid sump is a narrow range of types of contaminants that are affected by the magnet's attractive force. Another disadvantage is the use of a strainer, which, when contaminated, changes the hydrodynamic properties of the device and, consequently, the hydrodynamic properties of the entire system, which includes a sump. To remove settled sludge, it is necessary to disassemble the sump.

Known mud collector (RU Patent No. 2008604), in which the range of types of pollution from which water is purified is wider. It contains a housing with a bottom, with fluid inlet and outlet nozzles located on the same axis, a dirt outlet pipe and a filter located along the path of the fluid flow. A disadvantage of the known device is the need for periodic cleaning of the filter, because when it becomes dirty, firstly, it gradually loses its filtering properties, and, consequently, the level of cleaning, and secondly, changes the hydrodynamic properties of the device and, therefore, the hydrodynamic properties of the entire system, which includes the sump.

Known mud collector (RU Patent No. 54318), in which the range of types of pollution from which water is purified is wider. Also its advantage is that it does not need to be disassembled to remove settled sludge, since its design does not contain filters. The specified sump closest to the proposed combination of essential features and is selected as a prototype.

The design of the known sump includes a housing with a bottom with inlet and outlet nozzles located on the same axis and with nozzles for

dirt outlet, at least one of which is installed in the upper part of the casing, a pipe mounted in the casing on the same axis, with inlet and outlet pipes and rigidly connected to the output pipe installed in the bottom of the casing, and the opposite end of the pipe is closed by a baffling water-guiding surface, the shape of which allows water to slide along it towards the bottom, on the pipe, around it, along its length, water-guiding surfaces are installed, the shape of which allows water to slide along it towards the bottom, also on parts of the pipe overlapped water-guiding surfaces, longitudinal slots are made.

In the well-known sump, water-polluting heavy mechanical particles under the influence of gravitational forces accumulate in the bottom of the housing and can be removed through nozzles to remove dirt. But light mechanical particles, whose specific gravity is less than the specific gravity of water, do not fall on the bottom, but remain to float in the upper part or are carried away by a stream of water. The upper branch pipe is intended for cleaning from this type of pollution. But since water enters the sump under m pressure, light particles are constantly mixed with the incoming mass of water.

The task that the utility model is aimed at is the development of a mud collector design that allows you to effectively separate light fractions of pollutants and remove them, which does not require periodic disassembly of the device to restore filtering properties, and constantly provides a high level of cleaning.

The technical result is to increase the cleaning efficiency of the aqueous dispersion medium.

The technical result is achieved due to the fact that the proposed sump, as well as the known one, contains a housing with a bottom, with inlet and outlet nozzles located on the same axis, and with nozzles for removing dirt, at least one of which is installed in the upper part of the housing , a pipe mounted in the housing on one axis, with inlet and outlet pipes and rigidly connected to an output pipe installed in the bottom of the housing, and the opposite end of the pipe is closed by a baffling water-guiding surface, the shape of which allows water with roll along it toward the bottom, on the pipe, around it, along its length, water-guiding surfaces are installed, the shape of which allows water to slide along them toward the bottom, also longitudinal slots are made on parts of the pipe covered by water-guiding surfaces. But, unlike the known one, in the proposed mud sump, the outlet end of the inlet pipe is deepened into the inside of the body, and its edge expands towards the bottom.

With this embodiment, the mud collector, the liquid stream to be cleaned is supplied through the inlet pipe into the housing and flows under pressure to the baffle surface. Heavy fractions of pollution continue to move down, and light fractions float up. The expanding surface of the nozzle edge forms a chamber in the upper part of the casing, in which pollution emerging in the water accumulate and restricts the injection of pollution emerging in the upper part of the casing to the water flow entering the casing. Therefore, light fractions of contaminants do not mix with the rest of the water in the sump. The dirt accumulated above is periodically removed through the dirt outlet pipe located in the upper part.

The set of features set forth in paragraph 2 of the utility model formula characterizes a dirt collector in which the lengths of slots covered by water-guiding surfaces decrease sequentially in the direction from the inlet to the inlet.

The decreasing lengths of the slots overlapped by the water-guiding surfaces in the direction from the inlet to the outlet provide equalization of hydraulic pressure along the length of the pipe, which increases the efficiency of cleaning with a dirt collector.

The set of features set forth in paragraph 3 of the utility model formula characterizes the sump in which the bottom is conical.

This embodiment of the bottom provides a more complete removal of dirt through special nozzles to remove it.

The set of features set forth in paragraph 4 of the utility model formula characterizes the sump in which the bottom is flat.

This embodiment of the bottom simplifies installation of the device.

The set of features set forth in paragraph 5 of the utility model formula, including the features of paragraph 4, characterizes a mud collector in which, below the last water-guiding surface, there is a conical surface rigidly connected to the wall of the body, forming an acute angle with it from the bottom and its size is larger than the gap between the wall of the housing and the last water guide surface mounted on the pipe.

An additional cone-shaped surface, like a funnel, directs dirt to the location of the nozzle to remove dirt, so that it does not spread over a flat bottom.

The set of features set forth in paragraph 6 of the formula of the utility model characterizes the sump in which the upper part of the body is conical.

To remove light dirt particles, the cone-shaped surface allows you to concentrate them in a specific, narrowest place of the cone-shaped surface, from where they are removed through the pipe to remove dirt.

The set of features set forth in paragraph 7 characterizes a device in which each water-guiding surface has a conical shape.

The advantage of conical water-guiding surfaces is the simplicity of their manufacture.

The set of features set forth in paragraph 8, including the features of paragraph 7, characterizes a device in which each water-guiding surface is connected with its wide part to a cylindrical shell.

EFFECT: increased degree of purification is achieved due to the fact that in the proposed design of the mud collector there are no water turbulences that could entrain light particles into the stream of purified water due to the fact that the shells provide an even distribution of the water flow in the space between the body wall and the shell and quench the swirls of the stream.

The set of features described in paragraph 9 characterizes the device in which the generatrix of each water-guiding surface has an arcuate shape.

The use of water-guiding surfaces of a rounded shape, leads to an improvement in their hydrodynamic properties by reducing their hydraulic resistance, and, as a consequence, reducing the hydraulic resistance of the entire sump. In this case, the velocity field becomes equalized, the laminarity of the flow increases due to improved hydraulic flow around the rounded surfaces with water and reduced turbulence. The consequence of this is an increase in the degree of purification.

The set of features set forth in paragraph 10, including the characteristics of paragraph 9, characterizes a device in which each water-guiding surface is connected with its wide part to a cylindrical shell.

The set of features described in paragraph 11 of the formula of the utility model characterizes a dirt collector in which a manhole is made in the wall of the housing.

The manhole is used in the inoperative state of the device and allows you to get large dirt elements, such as stones, out of the sump.

The utility model is illustrated by the drawing, which shows a section of the proposed device.

The sump contains a housing 1, on one axis of which an inlet 2 and an outlet 3 nozzles are installed. A pipe 4 is mounted on the same axis in the housing and is rigidly connected to the outlet pipe 3. On the inlet pipe 2 side, the pipe 4 is closed by a water discharge surface 5. Around the pipe 4, along it, water-guide surfaces 6 are installed. the water-guiding surface has an arc shape, and each water-guiding surface is connected with its wide part to the cylindrical shell 7. On pipe parts overlapped, for example, by rounded surfaces, i.e. surfaces, the forming line of which has the shape of an arc, made longitudinal slots 8. The bottom 9 of the housing can be made flat. In front of the bottom in the direction of movement of water, a conical surface 10 is mounted, rigidly connected to the wall of the body, forming with it an acute angle from the side of the bottom 9, and its size is larger than the gap between the wall of the body and the last water guide surface mounted on the pipe.

At the bottom 9, nozzles 11 are installed to remove dirt. In the housing between the bottom and the conical surface 10 mounted on the housing, a hole 12 can be made, which is used to eliminate large foreign inclusions, for example, stones. The length of the longitudinal sections 8 decreases in the direction from the inlet to the outlet, since the flow loses its pressure as it flows through the sump and smaller holes are required to enter the pipe compared to those located above. The upper part of the housing can be made cone-shaped, and one or more nozzles 13 are installed in it for outputting light particles of dirt 13. For more effective removal of light particles, the inlet nozzle is recessed into the inside of the housing, and its edge has a shape expanding toward the bottom, for example, conical, separating upper layer of water contaminated with light inclusions from the rest of the water.

Cleaning with a sump is as follows. Through the pipe 2 in the housing 1 receives a stream of fluid to be cleaned. It falls onto the baffle surface 5 of the pipe 4 and flows smoothly over the entire cross-section of the housing 1. The stream flows around the first water-guiding surface, and due to the difference in the forces acting on either side of it, rotates 180 °, as a result of which heavy particles of impurities are separated and settle to the bottom

the sump, and the flow passes in the space between the inner part of the water-guiding surface 6 and the pipe 4, enters through the slots 7 into the pipe 4, and then into the outlet pipe 3. The pollution particles fall out during the rotation of the flow through 180 ° around the water-guiding surface under the influence of gravitational and pushing forces. This force difference is counteracted by the resistance force of the medium, which significantly decreases under the water-guiding surfaces 6 due to the creation of a laminar flow regime with slots 8 in the pipe. The space between the inner part of the water-guiding surface 6 and the pipe 4 provides a laminar flow regime of the medium at a speed of 0.05 m / s or less. This speed provides a high degree of purification from pollution. The flow rate of the medium for the second and subsequent conical surfaces is significantly reduced and the degree of purification of the environment from pollution increases.

Particles of contaminants whose specific gravity is greater than the specific gravity of water fall to the bottom, enveloping the conical surface 10 conjugated with the walls of the casing 1. Thanks to it, a settler is formed on the bottom of the casing, from which dirt particles cannot be carried away by the fluid flow from the casing due to sharp changes in the medium flow rate.

Particles of contaminants whose specific gravity is less than the specific gravity of water remain in the upper part of the sump. Due to the fact that the conical surface of the edge of the inlet pipe 2 separates the upper layer from the actively moving part of the water, light fractions (leaves, pieces of wood) are periodically removed through the pipe 13. But the cone-shaped edge of the inlet pipe not only separates the water layer, but also reduces spurious vortices at the water inlet in the mud casing, which trap particles of easily emerging contaminants and prevent them from collecting in the upper part of the apparatus.

Thus, the description of the construction of the mud sump and its operation indicate the achievement of a technical result - an increase in the efficiency of cleaning the liquid medium due to more efficient removal of light fractions of contaminants.

Claims (11)

1. The mud box, comprising a housing with a bottom, with inlet and outlet nozzles located on the same axis, and with nozzles for removing dirt, at least one of which is installed in the upper part of the housing, a pipe mounted in the housing on the same axis, with an inlet and an outlet nozzle and rigidly connected to an outlet nozzle installed in the bottom of the body, and the opposite end of the pipe is closed by a water-guiding surface whose shape allows water to slide along it toward the bottom, on the pipe, around it, along its length, a water supply is installed The grooving surfaces, the shape of which allows water to slide along them towards the bottom, also on the parts of the pipe overlapped by the water-guiding surfaces, longitudinal slots are made, characterized in that the output end of the inlet pipe is deepened into the inside of the body, and its edge is made expanding towards the bottom. 2. The sump according to claim 1, characterized in that the lengths of the slots located on the pipe are reduced sequentially in the direction from the inlet to the outlet. 3. The sump according to claim 1, characterized in that the bottom is conical. 4. The sump according to claim 1, characterized in that the bottom is made flat. 5. The sump according to claim 4, characterized in that below the last water guide surface there is a cone-shaped surface rigidly connected to the wall of the body, forming with it an acute angle from the bottom side, and its size is larger than the gap between the wall of the body and the last water guide surface mounted on the pipe. 6. The sump according to claim 1, characterized in that its upper part of the body is conical. 7. The sump according to claim 1, characterized in that each water-guiding surface has a conical shape. 8. The sump according to claim 7, characterized in that each water-guiding surface with its wide part is connected to a cylindrical shell. 9. The sump according to claim 1, characterized in that the generatrix of each water guide surface has an arcuate shape. 10. The sump according to claim 9, characterized in that each water-guiding surface with its wide part is connected to a cylindrical shell. 11. The sump according to claim 1, characterized in that at least one hole is made in the wall of the housing.