RU2817866C1 - Device for separating suspensions - Google Patents

Abstract

FIELD: various technological processes.

SUBSTANCE: invention relates to devices for separating suspensions. Device includes cylinder-conical housing, ensuring tightness of cylinder-conical housing upper and lower centring plates, upper block of bearings installed in upper centring plate, lower unit of bearings installed in lower centring plate, tangential branch pipe for inlet of initial suspension, thickened suspension discharge branch pipe, filtrate discharge branch pipe, filtering element installed on filtrate discharge branch pipe and made with possibility of rotation, drive shaft installed in the upper part of the filtering element and centred in the upper centring plate, discharge pipe is installed in the lower part of the filtering element and is centred in the lower centring plate. Filter element has an epicycloid cross-section, wherein the number of epicycloid cusps is not less than 4.

EFFECT: higher efficiency of a device for separating suspensions.

1 cl, 2 dwg, 1 tbl

Description

The invention relates to devices for separating suspensions and can be used in the chemical, food and other industries to separate the solid phase from the liquid phase.

A device for separating suspensions is known, including a cylindrical-conical body, upper and lower centering plates ensuring the tightness of the cylindrical-conical body, an upper block of bearings installed in the upper centering plate, a lower block of bearings installed in the lower centering plate, a tangential pipe for the input of the initial suspension, a pipe for the outlet of the thickened suspension, a pipe filtrate outlet, mounted on the filtrate outlet pipe and made rotatable, a filter element installed in the upper part of the filter element and centered in the upper centering plate, a drive shaft installed in the lower part of the filter element and centered in the lower centering plate, an outlet pipe [Utility model patent RU 204652 U1, 06/02/2021].

A disadvantage of the known device for separating suspensions is the small ratio of the surface area of the filter element to the area of the internal cylindrical surface of the cylindrical-conical body, which reduces the productivity of the device for separating suspensions.

The purpose of this invention is to increase the ratio of the surface area of the filter element to the area of the internal cylindrical surface of the cylindrical-conical body, which will improve the performance of the device for separating suspensions.

This goal is achieved by the fact that in the known device for separating suspensions, including a cylindrical-conical body, upper and lower centering plates ensuring the tightness of the cylindrical-conical body, an upper block of bearings installed in the upper centering plate, a lower block of bearings installed in the lower centering plate, a tangential pipe for introducing the initial suspension , a condensed suspension outlet pipe, a filtrate outlet pipe installed on the filtrate outlet pipe and a rotatable filter element installed in the upper part of the filter element and centered in the upper centering plate, a drive shaft installed in the lower part of the filter element and centered in the lower centering plate outlet pipe, the filter element in cross section has the shape of an epicycloid, and the number of epicycloid cusps is at least 4.

A device for separating suspensions, where the filter element in cross section has the shape of an epicycloid with 4 cusps, is shown schematically in Fig. 1, in fig. 2 shows section A-A of Fig. 1.

The device for separating suspensions includes a cylindrical-conical body 1, upper 2 and lower 3 centering plates ensuring the tightness of the cylindrical-conical body, an upper bearing block 4 installed in the upper centering plate 2, a lower bearing block 5 installed in the lower centering plate 3, a tangential pipe for introducing the initial suspension 6, condensed suspension outlet pipe 7, filtrate outlet pipe 8, installed on the filtrate outlet pipe and a rotatable filter element 9 installed in the upper part of the filter element and centered in the upper centering plate 2, drive shaft 10 installed in the lower part of the filter element and centered in the lower centering plate 3 there is an outlet pipe 11, and the filter element 9 in cross section has the shape of an epicycloid, and the number of epicycloid cusps is at least 4.

The initial suspension is fed through the tangential pipe for introducing the initial suspension 6 into the cylindrical-conical body 1, twists and, rotating, moves towards the filter element 9. Under the influence of the difference in the centrifugal force of inertia, the centripetal force of Archimedes and the drag force of the suspension flow, large particles move towards the wall of the cylindrical-conical body 1 and are discharged through the condensed suspension outlet pipe 7. Small particles, under the influence of the indicated forces, move along with the flow to the filter element 9 installed on the filtrate outlet pipe 8 and settle on its surface. The filtrate from the filter element 9 passes through the outlet pipe 11 and is discharged through the filtrate outlet pipe 8.

The filter element 9 is rotatable by rotating the filter element 9 installed in the upper part and centered in the upper centering plate 2 of the drive shaft 10.

The outlet pipe 11 installed in the lower part of the filter element 9 is centered in the lower centering plate 3.

The smoothness and uniformity of rotation of the filter element 9 is ensured by the upper 4 and lower 5 bearing blocks installed in the upper 2 and lower 3 centering plates, respectively, ensuring the tightness of the cylindrical-conical housing.

The rotation of the drive shaft 10 installed in the upper part of the filter element 9 and centered in the upper centering plate 2 can be carried out using an electric motor.

Table 1 shows an example of the ratio of the surface area s of a filter element having an epicycloid shape in cross section with the number of cusps from 1 to 10 to the area S of the internal cylindrical surface of the cylindrical-conical body of the device for separating suspensions. In this example, the diameters of the circle describing the epicycloid forming the cross section of the filter element and the circle forming the inner cylindrical surface of the cylindrical-conical body of the device for separating suspensions are equal. The height of the filter element and the height of the internal cylindrical surface of the cylindrical-conical body of the device for separating suspensions are equal. Results are presented rounded to the third decimal place.

Table 1 Number of epicycloid cusps 1 2 3 4 5 6 7 8 9 10 1 0.881 0.967 1.018 1.053 1,079 1,099 1.115 1.127 1.169

According to the results presented in Table 1, an increase in the ratio of the surface area of the filter element to the area of the internal cylindrical surface of the cylindrical-conical body will be achieved when the filter element is made in cross section in the shape of an epicycloid with a number of cusps of at least 4, where .

The implementation of a device for separating suspensions, where the filter element is rotatable by rotating the filter element installed in the upper part and centered in the upper centering plate of the drive shaft, and the filter element in cross section has the shape of an epicycloid, and the number of epicycloid cusps is at least 4, will increase the ratio of the surface area of the filter element to the area of the internal cylindrical surface of the cylindrical-conical body and thereby increase the productivity of the device.

Claims (1)

A device for separating suspensions, including a cylindrical-conical body, upper and lower centering plates ensuring the tightness of the cylindrical-conical body, an upper block of bearings installed in the upper centering plate, a lower block of bearings installed in the lower centering plate, a tangential pipe for the input of the initial suspension, a pipe for the outlet of the thickened suspension, an outlet pipe filtrate installed on the filtrate outlet pipe and a filter element rotatable, installed in the upper part of the filter element and centered in the upper centering plate, a drive shaft installed in the lower part of the filter element and centered in the lower centering plate, an outlet pipe, characterized in that the filter the element in cross section has the shape of an epicycloid, and the number of epicycloid cusps is at least 4.