RU2062658C1 - Rotor of centrifugal separator for liquid - Google Patents

Abstract

FIELD: chemical engineering. SUBSTANCE: rotor of centrifugal separator for liquid includes cylinder-conical foundation, cover connected with it, packet of dividing members mounted in rotor cavity and feeding pipe centrally located. Pipe has cone-shaped disk disposed above foundation bottom. Each dividing member represents removable chamber radially located and filled with hollow fibers. Chamber wall facing the cover and cover itself have shape of hyperboloid of rotation. Chamber wall facing the feeding pipe is made perforated. Perforated shell forming exhaust port for purified liquid is set up in space between chamber wall and feeding pipe. Innovation concerns centrifugal apparatuses for separating liquid nonhomogeneous systems and can be used in devices for fine cleaning of water and solutions. EFFECT: enhanced efficiency. 4 dwg

Description

 The invention relates to a centrifugation technique and can be used to separate liquids by the principle of separation in thin streams using hollow fibers in circulating water systems of industrial enterprises in the dairy, food, microbiological industries, including for concentrating solutions of high molecular weight substances.

 Known rotor of a centrifugal separator for liquid, including a cylindrical-conical base, a lid connected to it, a package of separation elements in the form of plates with spikes for thin-layer separation, a central supply tube with a cone-shaped disk located above the bottom of the base, and a collection device installed in the rotor cavity and removal of light and heavy liquids and solids / I /.

 A disadvantage of the known design of the rotor is that it does not provide a laminar flow of a vertical fluid flow, due to its large cross section.

 The deposition surface, and therefore the rotor productivity index is low, therefore, a high quality separation of heterogeneous systems can only be achieved with very low separator capacities. The vortex-like nature of the fluid flow between the plates is one of the main reasons for the insufficiently high quality of liquid separation.

 The technical result of the invention is to increase productivity and improve the quality of the separation of liquid heterogeneous systems, as well as the possibility of separation of colloidal systems or solutions.

 The technical result is achieved by the fact that in the proposed rotor of a centrifugal liquid separator, including a cylindrical-conical base, a lid connected to it, a packet of separation elements installed in the rotor cavity and a centrally located inlet tube with a cone-shaped disk located above the bottom of the base, each separation element is a radially located removable chamber filled with hollow fibers, while the chamber wall facing the lid and the lid are made in the form of a hyperbolo yes rotation, and the chamber wall facing the inlet tube is perforated, and a perforated shell is formed in the gap between it and the inlet tube, forming an outlet channel for purified liquid, and radially mounted ribs on the conical disk of the inlet tube to fix the chambers around the vertical axis of the rotor .

 The invention is illustrated in the drawing, in which figure 1 schematically depicts a longitudinal section of a rotor; FIG. 2 section aa of figure 1; figure 3 removable camera in a perspective view and figure 4 one of the side faces of the removable camera.

 The rotor of the centrifugal liquid separator includes a cylindrical-conical base 1 with a bottom 2, a cover 3 connected thereto, a package of separation elements 4 mounted in the rotor cavity and a centrally located supply tube 5 with a conical disk 6 located above the bottom of the base.

 Each dividing element 4 is a radially located removable chamber 7 filled with hollow fibers 8. The chamber wall 9 and the lid facing the lid 3 are made in the form of a rotation hyperboloid. The wall 10 of the chamber facing the inlet tube 5 is perforated. In the gap between it and the inlet tube, a perforated shell 11 is formed, which forms the outlet channel 12 for the purified liquid. On the conical disk 6 of the supply tube, radially ribs 13 are mounted to fix the chambers around the vertical axis of the rotor.

 The removable chambers 7 are pulled together from the side of the outer cylindrical face 14 and pulled together by a net 15. In the upper part they are interconnected by an annular rubber seal 16. The rotor cover is connected to the base with a nut 17.

 Each removable camera 7 has vertical side faces 18 and 19 and a flat bottom 20 having the shape of a truncated cone (see figure 3). Hollow fibers 8 fill the entire internal volume of the chambers so that the end ends of the fibers on one side form the outer cylindrical face 14, and on the other hand come in contact with the perforated wall 10. The bottom of the chamber 7 has bases located at radii r and R from the vertical axis of rotation ( see figure 4). The two vertical sides of faces 18 or 19 have dimensions h and H, where h is the height of the outer cylindrical face 14, H is the height of the perforated wall 10. The curved side of the flat face 18 or 19 is made along a hyperbole. The change in the height of the faces obeys the hyperbola equation.

In FIG. 4 also shows the values of H _{z the} variable value of the height of the flat face 18 or 19 and r _{z the} radius of the point on the generatrix of the conical bottom 20, for which H _z is determined.

где a угол конусности конического днища 20;
Z вертикальная координата, отсчитываемая от нижнего основания конуса с радиусом R.The design of removable chambers ensures the constancy of the size of their vertical cylindrical sections, due to the shape of the hyperboloid of revolution. From this condition it follows that

where a is the taper angle of the conical bottom 20;
Z is the vertical coordinate measured from the lower base of the cone with radius R.

The obtained dependence between the parameters H _z , h, H, R, r _z , Z and a determines the shape of the removable camera.

 The rotor operates as follows.

 The initial liquid is supplied under small pressure to the cylindrical part of the supply tube 5, then to the cavity formed by the conical bottom 20 of the removable chambers 7 and the conical surface of the bottom 2 of the base 1. An annular liquid flow goes around the edges of the removable chambers 7 and rushes upward, washing cylindrical faces 14 from the periphery chambers 7, pulled together by a grid 15. Once in the hollow channels of the fibers 8, the liquid is divided into many capillary flows meridionally directed from the periphery to their apex, with angles of inclination to the axis of rotation defined by night 9 and the bottom 20 of the camera 7.

 The shape of the chambers 7 ensures the constancy of the areas of vertical cylindrical sections, which guarantees the equality of the meridional velocities of the fluid flows along the length of the fibers.

 Under the action of centrifugal forces, denser inclusions dissolved in the liquid or in a colloidal state are displaced into the fiber channel zones that are farthest from the axis of rotation of the rotor. The released inclusions form a dense film moving along the walls of the hollow fibers towards the main fluid flow. Drops of concentrate flowing from the fibers are collected in the slurry zone of the rotor. As it accumulates, the concentrate is displaced to the annular gap between the rotor cover 3 and the walls 9 of the chambers 7 and is discharged separately from the purified liquid by one of the known devices, for example, a pressure disk. The purified liquid flowing from the upper holes of the fibers enters through the perforated walls 10 of the chambers and the perforated shell 11 into the cylindrical gap between the inlet pipe 5 and the wall of the shell and moves upward and discharged by the pressure disk (not shown).

 The design of the rotor allows you to increase the performance of the separator and to improve the quality of the separation of liquid heterogeneous systems, in particular containing high molecular weight substances. YYY2

Claims (1)

 The rotor of a centrifugal separator for liquid, including a cylindrical-conical base, a lid connected to it, a package of separation elements installed in the rotor cavity and a central supply pipe with a cone-shaped disk located above the bottom of the base, characterized in that each separation element is a radially removable a chamber filled with hollow fibers, while the chamber wall and the lid facing the cover are made in the form of a hyperboloid of revolution, and the chamber wall is facing I am perforated to the inlet tube, and a perforated shell is formed in the gap between it and the inlet tube, which forms the outlet channel for the cleaned liquid, and radially ribs are mounted on the cone-shaped disk of the inlet tube to fix the chambers around the vertical axis of the rotor.

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