SU1097355A1 - Pulser - Google Patents

Abstract

PULSATOR, including a cylindrical body with pipes for pulsation, feeding and etching, a rotor made in the form of a hollow cylinder divided by a longitudinal partition, characterized in that, in order to increase reliability, it is provided with an additional partition mounted in the inner cavity of the rotor and the partition camera on the cell, while the oppositely located chambers are interconnected by channels.

Description

The invention relates to devices for creating pulsations in chemical technology apparatuses and can be used in the chemical petrochemical and other industries for intensifying the masses of metabolic processes. A pulsator is known that includes a cylindrical bore, nozzles for pooling, feeding and etching, a rotor made in the form of a spool G 1 3However, this device cannot be used to generate a full-wave pulsation necessary for the intensification of dynamically balanced devices. The rotor feedthroughs have significant hydraulic resistance. A pulsator is also known, which includes a cylindrical body, pulsation, feed and drain nozzles, a rotor made in the shape of a hollow cylinder 21. However, the known device is also not applicable to create a full-wave pulsation and has a strong resistance. Closest to the proposed technical essence and the achieved result is a pulsator containing a cylindrical body with nozzles for pulsation, feed and discharge, a rotor made in the form of a hollow cylinder divided by a longitudinal partition t3. The disadvantage of this pulsator is low reliability, due to the significant radial alternating dynamic loads on the rotor plate, arising during the operation of the pulsator. Loads of this nature significantly reduce the life of the pulsator. The purpose of the invention is to increase the reliability of the pulsator. The goal is achieved by the fact that a pulsator comprising a cylindrical body with supply and bleed pulsation nozzles, a rotor made in the form of a hollow cylinder divided by a longitudinal partition is provided with an additional partition installed in the inner cavity of the rotor and dividing it into four chambers, while the oppositely located chambers connected together via channels. This embodiment of the rotor can significantly improve the reliability of the pulsator by changing the nature of the dynamic loads that occur during the operation of the pulsator. Supplying the rotor with an additional plate and pairing the opposite chambers completely eliminates the radial alternating loads on the rotor. FIG. 1 shows a pulsator, a longitudinal section; in fig. 2 shows section A-A in FIG. 1, in FIG. 3 shows a section BB in FIG. 2. The pulsator consists of a body. 1, the rotor 2, the supply nozzles 3 and the bleed 4 liquid, the pulsation nozzles 5 and 6. The rotor 2 is divided by a partition 7 and an additional partition 8 into four chambers 9, 10, 11 and 12, which are connected in pairs by channels 13 and 14 and form two cavities 15 and 16. The cavity 15 is connected with the supply nozzle 3, and the cavity 16 with the liquid bleeding nozzle 4. A slot 17 is made on the rotor's cylindrical surface. The pulsator operates as follows. When the rotor 2 rotates during the first quarter of the period, the pulsation nozzles 5 are connected to the high pressure cavity 15 through slots 17 in the cylindrical surface of the rotor, the pulsation nozzles 6 - with the low pressure cavity 16 through the slots 17. High pressure pulses are generated in the pulsation nozzles 5, in the nozzles 6. - low pressure pulses. In the next quarter of the period, the sign of the pulses in the pulsation nozzles is reversed. Since chambers 9 and 10, which form the high pressure cavity 15, as well as chambers 11 and 12, which form the low pressure cavity 16, are diametrically opposite to each other and symmetrically relative to the longitudinal axis of the rotor 2, the radial forces acting on the rotor 2 are mutually compensated and The force acting on the rotor is directed along its central axis from the high cavity and the low pressure cavity. The magnitude of this force depends on the cross-sectional area of the rotor and on the pressure drop between the cavities.

15 and 16 of the rotor 2, the direction remains constant.

- Elimination of radial alternating loads on the rotor shaft eliminates shock loads on the pulsator bearing assemblies, which allows to significantly increase the service life and increase the reliability of the trouble-free operation of the pulsator.

A prototype pulsator was tested on a pilot extraction plant.

A pulsator with a rotor with a diameter of 150 ml was installed in full-scale, ONE system for creating pulsations of the pilot plant. Tests have shown the operability of the mechanism1,

its reliability. During the operation of the pulsator there were no vibrations and shocks.

A spool type pulsator is taken as the basic object, widely used in industry in pulsating extraction installations.

Spool pulsators have significant hydraulic resistance due to the complex shape of the flow channel, which prevents their use in hydraulic systems for creating pulsations.

The use of the proposed pulsator as compared with the base object allows reducing energy costs for creating pulsations, increasing the reliability of operation of pulsating extraction plants.

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Claims (1)

PULSATOR, comprising a cylindrical body with pulsation, supply and bleed nozzles, a rotor made in the form of a hollow cylinder separated by a longitudinal partition, characterized in that, in order to increase reliability, it is equipped with an additional partition installed in the inner cavity of the rotor and separating it into four cameras, while the oppositely located cameras are interconnected via channels. SU ... 1097355