SU1526727A1 - Pulser - Google Patents

Abstract

The invention relates to pulsators and allows to simplify the design and increase the reliability of operation. The pulsator contains a cylindrical body with pipes for pulsation, supply and removal of fluid in which the rotor is placed. On the cylindrical surface of the rotor at its ends there are annular grooves and screw grooves communicated with them at one end. The supply and discharge nozzles are located opposite the corresponding annular grooves, and the pulsation nozzles are located opposite the corresponding helical grooves. 1 hp f-ly, 2 ill.

Description

The invention relates to chemical technology and may find application in the chemical, petrochemical, and other industries.

and, the spruce of the invention is to simplify the design and increase the reliability of the pulsator.

FIG. I shows the pulsator, general view, in section; in fig. 2 is a view A of FIG. one.

Pu1cator consists of a housing I with nozzles of fluid supply 2, a drainage of fluid 3 and nozzles 4 and 5 of fluid pulsation, a rotor 6 with cuts on a cylindrical surface in the form of an annular groove 7 and a helical groove 8 connected to it at one end, as well as an annular groove 9 and a screw groove 10 connected to it by one cone. A supply nozzle 2 is connected to a high pressure nozzle of a constant pressure source 1 1, and a nozzle 3 is connected to a low pressure nozzle of a source 11. A pulsation nozzle 4 is connected to an annular zone 12, a pulsation nozzle 5

Soi: 111nen with the central zone of L techno. unit 14. The nozzles 2 and 3 of the fluid supply and drain are placed opposite the annular grooves 7 and 9, and the nozzles 4 and 5 of the pulsation are opposite the helical ones 8 and 10. To eliminate the dynamic pressure of the fluid flow on the rotor, the nozzles 2 and 3 placed tangentially to the pulsator body. The helical grooves 8 and 10 are made with the same niaroM and are offset from each other by half a step. To ensure uniform distribution of pressure in the cavity of the pulsator, the helical grooves 8 and 10 must have at least one turn.

Pulsator works as follows.

Fluid from a constant pressure source 1 1 through a feed inlet 2, an annular groove 7, a helical groove 8 and a pulsation nozzle 5 enters the annular zone 12 of the apparatus 14, the level of which begins to rise. At the same time, source 11 is constantly

sd y

a to

pressure drop through the pipe 3, the annular groove 9, the screw groove 10 and the pipe 4 pulsation, the liquid is sucked from the central zone 13 of the apparatus 14. The level of the liquid in which begins to decrease. When the rotor 6 is rotated half a turn of the screw, the groove 8 is positioned against the pipe 4, and the screw groove 10 is against the pipe 5. At the same time, through the pipe 4, the liquid is supplied to the annular zone 12 of the apparatus 14, and through the pipe 5 the liquid is withdrawn from the central zone 13 of the apparatus 14. After every half-turn of the rotor 6, the direction of the pressure of the fluid in the nozzle x 4 and 5 is reversed. Similarly, when the rotor 6 rotates under the action of a constant pressure drop in the grooves x 8 and 10 in the nozzles 4 and 5, there is a periodic change in the direction of fluid movement, which leads to periodic fluctuations in the fluid level in the zones of the process apparatus. This significantly simplifies the design of the pulsator, its manufacture and maintenance.

In addition, due to the provision of high and low pressure chambers in the form of annular grooves, smoothly connected to the screw grooves and located on the outer surface of the rotor, the hydraulic resistance of the pulsator is significantly reduced, and due to the developed cylindrical surface of the rotor, high and low chambers are sealed pressure

five

0

five

0

Research institutes, losses from liquid flows are reduced, and the performance of the pulsator is increased. In addition, due to the annular and helical grooves on the surface of the cylindrical rotor and the tangential supply and removal of fluid, the dynamic forces acting on the rotor are completely balanced. This pulsator design allows the rotor to be installed without special supports and additional sealing devices, which significantly increases the reliability of the pulsator.

Claims (2)

1. A pulsator comprising a cylindrical body with pulsation, supply and drainage nozzles, in which a rotor is placed in the form of a cylinder with cutouts on a cylindrical surface, characterized in that, in order to simplify the design and increase reliability, the cutouts are made as placed on the ends of the rotor annular grooves and communicated with each of them by one end of the helical grooves displaced one from + yusite.no the other, while the supply and discharge nozzles are placed opposite the corresponding annular grooves, and the surge nozzles - in front of the respective helical grooves. 2. A pulsator according to claim 1, characterized in that the supply and discharge nozzles are arranged tangentially to the body.  YU 1, liZT rza I I I Jl 1 G / / ... / /// / / y / y / X-./ 12, /  eg 5 y / /  eg 3 Zid FIG. 2