RU123335U1 - RADIAL RESTAURANT - Google Patents

Abstract

1. A radial sump for cleaning a liquid medium, comprising a generally cylindrical body, inlet and outlet pipelines, means for draining the clarified liquid and a sludge collection system configured to rotate, including at least one sludge collector connected to the discharge sludge pipe, and at least at least one adjustment unit, characterized in that the adjustment unit includes an adjustment element with a constant pre-set flow area. 2. The radial sump according to claim 1, characterized in that the sludge collector is connected to a discharge sludge pipe through an adjustment unit. The radial sump according to claim 1, characterized in that the adjusting element is a washer. Radial sump according to claim 1, characterized in that the adjusting element is a diaphragm with a hole. The radial sump according to claim 1, characterized in that the sludge collectors are mounted concentrically on the discharge sludge pipe. The radial sump according to claim 4, characterized in that the size of the installed passage section depends on the radius of the concentric circle described by the sump when the sludge is rotated.

Description

The utility model relates to the field of treatment facilities, in particular to radial sumps, and can be used for cleaning liquid media.

The methods used for cleaning liquid media can be divided into three groups: mechanical cleaning, physico-chemical and biological treatment. Mechanical cleaning is performed to isolate undissolved coarse dispersed impurities from the liquid medium by filtering, settling and filtering. To isolate suspended solids from a liquid medium, particles of which have a higher or lower density in comparison with the density of the settled liquid, sedimentation is used. In this case, heavy particles are deposited to the bottom under the action of gravity, and light float to the surface. Sludge falling to the bottom of sedimentation tanks must be continuously or periodically removed. The duration of its storage period depends on the amount of sediment and its ability to rot and compact. Slightly decaying sediments such as domestic sewage sludge and a number of industrial effluents from the food industry can be stored for no more than a day. Decay of the sediment leads to re-contamination of the sedimented liquid medium and violation of the sedimentation regime, which generally leads to a decrease in the efficiency of the radial sedimentation tank. Therefore, the urgent task remains to develop new structural elements of treatment facilities that will allow the most efficient collection of sludge from the bottom of the sump.

The closest analogue of the claimed utility model is the sump described in UK patent No. 1501480, containing a generally cylindrical housing supporting a bridge truss located above the housing and configured to rotate in an annular groove located on the edge of the sump housing, a sludge collector and a discharge sludge pipe attached to a supporting bridge farm and installed in the casing so that when using sludge collectors, sludge is collected from the bottom of the sump casing. Each sludge collector is connected to a discharge sludge pipe through a conductive pipe on which the control unit is mounted. At the same time, the control unit is a valve, with the possibility of flushing the sludge collector and the outlet sludge pipe with a reverse flow.

The disadvantage of the described solution is the location of the discharge sludge pipe and the control device at the interface, where the oxidation of the metal surface is most intense, as a result of which the efficiency of the control unit is impaired. Another drawback of this solution is the inability to control the amount of sludge intake from the bottom of the sump, which leads to stagnation of the collected sludge in the pipe, and as a result leads to the need to wash the sludge and the outlet sludge pipe.

The utility model is based on the task of developing a radial sump, which, due to the design of the control unit, will provide the ability to control the amount of sludge intake by a sludge collector, which will simplify maintenance of the sludge collection system of the radial sump.

The problem is solved in that a radial sump for cleaning a liquid medium is developed, containing a generally cylindrical body, inlet and outlet pipelines, means for draining clarified liquid and a sludge collection system, including at least one sludge collector connected to a discharge sludge pipe, and an adjustment unit wherein the adjustment unit includes an adjustment element with a constant pre-installed passage section. The housing contains a flat bottom. In the center of the casing is a hollow support column, on which a bridge truss and a guiding device are installed. The guiding device is made in the form of a cylindrical wall mounted so that the liquid medium, when supplied to the sump, does not overflow through the guiding device. The bridge truss is rotatably mounted relative to the hollow support column. The sludge collection system is installed in a radial sump with the possibility of rotation relative to the hollow-column of the support together with the bridge farm. The adjustment unit is made in the form of a flange connection, between the flanges of which an adjustment element is installed. This embodiment of the utility model allows for the ability to control the amount of sludge intake by a sludge collector.

It is advisable to implement a utility model in which the sludge collector is connected to a discharge sludge pipe through an adjustment device. Connection through an adjusting device is a pipeline connection in which one of the flanges of the adjusting unit is part of a sludge collector. This embodiment of the utility model provides maximum efficiency of the regulatory unit. Also, this design provides ease of maintenance.

It is preferable to perform the inventive device in which the adjusting element is a washer or diaphragm with a hole. The diameter of the hole is calculated based on the throughput under the influence of hydrostatic pressure of the liquid column. The adjusting element may be made of easily processed material selected from the group including steel, plastic, rubber. This design of the radial sump provides the ability to quickly replace the adjusting element if necessary.

It is advisable to perform a utility model in which sludge collectors are mounted concentrically on the outlet sludge pipe. The concentric installation of sludge collectors is a displacement of sludge collectors by a certain step relative to each other, while the point relative to which rotation of the sludge collection system is possible remains common. Thus, the collection of sludge from the entire surface of the bottom of the sump.

It is also advisable to implement a utility model in which the size of the installed flow cross section depends on the radius of the concentric circle described by the sump when turning the sludge pipe. With an increase in the radius of the concentric circle, the area of the bottom sector of the radial sedimentation tank under the sludge tank increases, and, consequently, the amount of sediment that must be removed by a specific sump increases. For this purpose, in the sludge collection system at the installation site of the adjustment unit, an increase in the flow area is necessary. Thanks to this embodiment of the utility model, it is possible to change the flow area depending on the amount of sediment collected.

The utility model is illustrated using the graphic materials below.

Figure 1 presents a General view of the radial sump in section;

Figure 2 shows the layout of the adjustment unit.

Figure 1 shows a General view of the radial sump in section, containing a generally cylindrical body 1, in the center of which is a hollow support column 2. Also, the radial sump contains a supply pipe 3 and a discharge pipe 4 and means 5 for draining the clarified liquid. To remove sludge from the bottom surface of the radial sump, a sludge collection system 6 is installed. The sludge collection system 6 includes a sludge collection pipe 7 on which a sludge collector is installed 8. The sludge collector 8 and the sludge collection pipe 7 are connected through an adjustment unit 9.

Figure 2 shows the location of the adjustment unit 9. The adjustment unit 9 is installed on the pipeline that connects the collection pipe 7 and the collection tank 9. In the adjustment unit, the adjustment element 10 is installed.

The inventive utility model is implemented as follows.

Preliminarily calculate the size of the cross-section of the pipeline connecting the sump 8 to the sump 7, depending on the location of the sump 8, in order to equalize the hydraulic pressure by installing the adjustment unit 9. In the adjustment unit 9 install the adjustment element 10, made in the form of a washer and / or diaphragm with a hole. The diameter of the hole made in the adjusting element 10 is calculated depending on the required throughput. The initial liquid medium is supplied through a supply pipe 3 to the inner region of the cylindrical body 1. The liquid medium is evenly distributed in the volume of the sump and sent in a radially ascending direction to the periphery of the housing. The clarified liquid is poured over the side of the means 5 for draining the clarified liquid and is withdrawn by means of a discharge pipe 4. The separation and precipitation of the solid phase are carried out by moving the liquid flow from the center to the periphery of the housing 1, while the solid phase is collected and compacted on the bottom surface. The compacted sediment is collected from the surface of the bottom using a sludge collection system 6. As a result of changes in the properties of the sludge, the sediment deposition patterns on the bottom of the sump change over time. With an increase in the volume of incoming sludge into the sludge collector, the adjusting element 10 is replaced by an element with an increased flow area. In the case of a decrease in the volume of incoming sludge, the adjusting element 10 is replaced by an element with a reduced flow area. The replacement of the adjusting elements is carried out after draining the sump.

Thus, the developed radial sump due to the design of the regulatory unit provides the ability to control the amount of sludge intake by a sludge collector. Through this design of the radial sump, the maintenance of the sludge collection system is simplified, and the economic feasibility of introducing the inventive sump is also ensured.

Claims (6)

1. A radial sump for cleaning a liquid medium, comprising a generally cylindrical body, inlet and outlet pipelines, means for draining the clarified liquid and a sludge collection system configured to rotate, including at least one sludge collector connected to the discharge sludge pipe, and at least at least one adjustment unit, characterized in that the adjustment unit includes an adjustment element with a constant pre-set flow area. 2. The radial sump according to claim 1, characterized in that the sludge collector is connected to a discharge sludge collector through an adjustment unit. 3. The radial sump according to claim 1, characterized in that the adjusting element is a washer. 4. The radial sump according to claim 1, characterized in that the adjusting element is a diaphragm with a hole. 5. The radial sump according to claim 1, characterized in that the sludge collectors are mounted concentrically on the outlet sludge pipe. 6. The radial sump according to claim 4, characterized in that the size of the installed passage section depends on the radius of the concentric circle described by the sump when the sludge is rotated.