RU157377U1 - LIQUID ACTIVATOR - Google Patents

Abstract

An activator of liquid media, including a tubular flow chamber, in which a vortex chamber is placed, which is rotated by means of electric windings relative to the flow chamber, while the vortex and flow chambers are provided with vanes fixed on their inner surfaces and having a mutually opposite installation angle, while the vortex vanes the chambers are made in the form of a spiral, characterized in that the blades of the flow chamber are made in such a way that they form confusers at the entrance to the interscapular channels, and diffusion at the exit ora, while inside the flow chamber coaxially installed ring, the outer surface connected to the blades of the flow chamber.

Description

The utility model relates to the mining industry, namely to the activation of liquid media, for example filling mixtures, in the process of their transportation through the pipeline to the place of laying.

Known activator of liquid media A.S. on the invention No. 1654603 A1, E21F 15/08, publ. 06/07/91. Bull. No. 21, ed. IN AND. Shtele, I.Ya. Kusins, A.N. Anushenkov.

An activator of liquid media, including a tubular flow chamber, in which a vortex chamber in the form of a ring with a drive is mounted, mounted for rotation relative to the flow chamber. The flow chamber is made of magnetically permeable material with annular recesses on the inner surface, and the vortex chamber drive is made in the form of electric windings located concentrically on the outer surfaces of the flow and vortex chambers in the interval of these recesses.

The disadvantage of this activator is that the activator does not provide a sufficient intensity of exposure to the mixture.

The closest in technical essence and the achieved result is a patent for utility model RU No. 126369U1, E21F 15/00 (2006.01) Activator of liquid media (options), (option 2), dated 10.09.2012 Stovmanenko A.Yu., Anushenkov A.N . publ. 03/27/2013, adopted as the closest analogue (prototype).

An activator of liquid media, including a tubular flow chamber, in which is placed a vortex chamber, driven into rotation by means of electric windings, relative to the flow chamber. The vortex and flow chamber are equipped with blades mounted on their inner surfaces and having a mutually opposite installation angle, while the blades of the vortex chamber are made in the form of a spiral.

The lack of activator is also the lack of intensity of the mechanical effect of the mixture.

The objective of the utility model is to increase the intensity of the mechanical action of the activator on the mixture.

This is achieved by the fact that the activator of liquid media, including a tubular flow chamber, in which a vortex chamber is placed, which is rotated by means of electric windings relative to the flow chamber, while the vortex and flow chamber are equipped with blades mounted on their inner surfaces and having a mutually opposite installation angle while the blades of the vortex chamber are made in the form of a spiral, and the blades of the flow chamber are made in such a way that they form confusers at the entrance to the interscapular channels, and at the exit fusors, while inside the flow chamber a ring is coaxially mounted, the outer surface connected to the blades of the flow chamber.

A sharp change in the speed and direction of movement, as well as a change in the static and dynamic pressure in the mixture during successive passage through the confuser and diffuser of the interscapular channel of the blades of the flow chamber, increases the intensity of the mechanical action of the activator on the mixture, and the ring connected by the outer surface to the blades of the flow chamber reduces flow mixtures from the interscapular canal.

The device is illustrated graphically in FIG. 1 and FIG. 2.

The activator of liquid media contains a vortex chamber 1 (Fig. 1), bearings 2, a flow chamber 3, the walls of the housing 4, the electric drive housing 5, the stator windings 6 mounted on the housing 5 and the rotor windings 7 mounted on the vortex chamber 1. On the inner surface tubular vortex chamber 1, fixed blades 8, made in the form of a spiral. Blades 9 are fixedly mounted on the inner surface of the tubular flow chamber 3. Seals 10 are installed to seal the vortex and flow chamber. The activator is connected to the pipe 11.

The blades 9 of the flow chamber 3 (Fig. 2) have a special shape. The shape of the blades 9 is made in such a way that confusers 12 are formed first, and then diffusers 13 are formed in the interscapular channels 14. The ring 15 is mounted coaxially inside the flow chamber 3, and the outer surface of the ring 15 is connected to the blades 9.

The activator works as follows.

In the electric coil 6 (Fig. 1), a rotating electromagnetic field is created, and in the short-circuited winding 7, under the influence of a rotating magnetic field, an electromotive force is induced and a torque arises, due to which the vortex chamber 1 rotates. From the vortex chamber 1, the rotation is transmitted to the blades 8.

The rotation of the blades 8 provides an increase in the pressure of the mixture at the outlet of the activator. In addition, a complex mechanical effect is created on the transported liquid medium, during its subsequent interaction with the motionless blades 9, of the flow chamber 3. In this case, intensive mixing of the flow, accompanied by activation of the mixture, leads to frequent collisions of the particles of the mixture, their destruction, grinding and increasing the uniformity of the composition mixtures. The seals of the vortex chamber 10 ensure the uninterrupted operation of the activator.

During the passage of the mixture through the interscapular channels 14 formed by the blades 9 of the flow chamber 3 (Fig. 2), the mixture first enters the confusers 12 at the inlet of the interscapular channels 14. In this case, the dynamic pressure in the mixture increases and the static pressure decreases. In addition, also increases the flow rate of the mixture in the interscapular channels 14. When the mixture subsequently enters the diffusers 13 at the exit of the interscapular channels 14, the dynamic pressure of the mixture decreases and the static pressure increases, while the flow rate of the mixture also decreases. The ring 15, the outer surface of which is connected with the blades 9, reduces the flow of the mixture from the interscapular channels 14 to the center of the flow chamber 3.

Sudden changes in the speed and direction of the flow of the mixture, changes in the static and dynamic pressure in the mixture as it passes through the confusers 12 and diffusers 13 of the interscapular channels 14, increase the intensity of the mechanical action of the activator on the mixture, accompanied by its additional activation. Reducing the flow of the mixture from the interscapular channels 14 also increases the degree of activation of the mixture.

Claims (1)

An activator of liquid media, including a tubular flow chamber, in which a vortex chamber is placed, which is rotated by means of electric windings relative to the flow chamber, while the vortex and flow chambers are provided with vanes mounted on their inner surfaces and having a mutually opposite installation angle, while the vortex vanes chambers are made in the form of a spiral, characterized in that the blades of the flow chamber are made in such a way that they form confusers at the entrance to the interscapular channels, and diffuse at the exit ora, while inside the flow chamber coaxially installed ring, the outer surface connected to the blades of the flow chamber.

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