RU201015U1 - A device for lifting bulk materials in a transport pipeline - Google Patents

Abstract

The device relates to pipeline transport, namely, lifting devices with vertical and inclined from the vertical pipelines with an increased concentration of bulk materials in the carrier medium. The device for lifting bulk materials in the transport pipeline contains inclined and vertical sections. Transverse perforated inserts are installed on the longitudinal elements of the frames movably along the height with the possibility of changing the distance between them in the process of reconfiguring the lift depending on the change in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium, which does not exceed the value determined by the dependence: where Hper is the distance between the transverse perforated inserts, m; Н0 - height of a fixed (filtering) layer of particles of bulk material, m; W is the air flow speed, m / s; WKR - critical fluidization velocity of bulk material, m / s, while maintaining the set value along the entire height of the pipeline, while the distance between the transverse perforated inserts should not exceed 5 diameters of the transport pipeline. depending on changes in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium to increase the reliability of the hoist and reduce energy consumption. 2 ill.

Description

The device relates to pipeline transport, namely to lifting devices with vertical and inclined from the vertical pipelines with an increased concentration of bulk materials in the carrier medium.

Known devices for lifting bulk materials in a transport pipeline, containing a vertical and inclined from the vertical transport pipeline and dispersedly installed in it transverse perforated inserts. (Patent RU No. 2194661. A device for lifting bulk materials with increased concentration in a gas mixture. Publ. 20.12.2002. Bull. No. 35; patent RU No. 2294886. A device for lifting bulk materials with an increased concentration in a gas mixture. Publ. 10.03. 2007. Bulletin No. 7; Patent RU No. 138223. Device for continuous lifting of bulk materials. Publ. 03/10/2014. Bulletin No. 7).

In these devices, oriented reinstallation of the transverse perforated inserts in a given position along the height is difficult, depending on the technical and economic parameters of the lift, which leads to a decrease in the reliability of its operation and an increase in energy consumption.

It is also known a device for lifting bulk materials in a transport pipeline, containing a vertical and inclined from the vertical transport pipeline, in which the transverse perforated inserts are dispersedly mounted on the longitudinal elements of the frames, which are located in the internal cavities of the mentioned sections of the pipeline. (Patent 157658. A device for lifting bulk materials. Publ. 10.12.2015. Bull. No. 34).

In this device there is no possibility of changing the distance between them in the process of reconfiguring the elevator, depending on the properties of the transported material, taking into account the set value.

The task of the proposed device is to ensure a change in operating and design parameters in the process of reconfiguring the elevator, depending on the change in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium to increase the reliability of the elevator and reduce energy consumption.

The task is achieved by the fact that in a device for lifting bulk materials in a transport pipeline containing inclined and vertical sections, in which the transverse perforated inserts are dispersedly installed on the longitudinal elements of the frames located in the internal cavities of the pipeline, the transverse perforated inserts are installed on the longitudinal elements of the frames movably along height with the possibility of changing the distance between them in the process of reconfiguring the lift, depending on the change in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium, not exceeding the value determined by the dependence:

where H _lane is the distance between the transverse perforated inserts, m; H ₀ - the height of the stationary (filtering) layer of particles of bulk material, m; W is the air flow speed, m / s; W _KR - critical fluidization velocity of bulk material, m / s, while maintaining the set value along the entire height of the pipeline, while the distance between the transverse perforated inserts should not exceed 5 diameters of the transport pipeline.

FIG. 1 schematically shows the proposed device; in fig. 2 shows the dependence of the ratio of the height of the fluidized bed to the height of the stationary gas velocity.

The device for lifting bulk materials contains a mixing chamber 1 with a vertical transport pipeline 2. In the lower part of the mixing chamber, there are nozzles 3 for supplying compressed air and a porous gas distribution baffle 4. The feeding part 5 of the mixing chamber 1 is located above the inlet nozzle 6 of the transport pipeline 2. Transverse inserts 7 in the form of lattices are installed in the inner cavity of the pipeline 2 on the longitudinal elements of the frame 8 movably in height.

According to the results of design and experimental work, the graph (Fig. 2) shows the dependence of the ratio of the height of the fluidized bed to the height of the stationary gas velocity. These results showed that the ratio Н / Н ₀ can be approximated by the dependence:

where H is the height of the fluidized bed, m; H ₀ - the height of the stationary (filtering) layer of particles of bulk material, m; W is the air flow speed, m / s; W _KR - critical velocity of fluidization of bulk material, m / s. For alumina particles of size 25 microns minus W _SF = 0.00047 m / s.

For our case, the transverse inserts 7 in the form of lattices are installed movably along the height with the possibility of changing the distance H _lane between them in the process of reconfiguring the lift, which does not exceed the value determined by the dependence:

and taking into account the change in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium, m / s, while maintaining the set value along the entire height of the pipeline, while the distance between the transverse perforated inserts should not exceed 5 diameters of the transport pipeline.

Bulk material from the feeding part 5 continuously enters the mixing chamber 1. The carrier medium is fed through the porous partition 4 under the layer of bulk material. Aerated bulk material with increased concentration is fed into pipeline 2 through its inlet pipe 6. Due to the differential pressure of compressed air, the bulk material moves through pipeline 2 in a decelerated state by creating additional resistances in the form of transverse inserts 7 with holes installed dispersed along the height of the pipeline 2 s a certain step H _lane . Material particles sequentially flow through the openings of the transverse inserts 7 under the action of the differential pressure of compressed air, rising through the pipeline. By means of transverse inserts 7, the material flow is aligned over the entire section of the pipeline.

This device provides a change in operating and design parameters in the process of reconfiguring the lift to increase the reliability of the lift and reduce energy consumption.

Claims (3)

A device for lifting bulk materials in a transport pipeline containing inclined and vertical sections, in which the transverse perforated inserts are dispersedly installed on the longitudinal elements of the frames placed in the internal cavities of the pipeline, characterized in that the transverse perforated inserts are installed on the longitudinal elements of the frames movably in height with the possibility changes in the distance between them in the process of reconfiguring the lift depending on the change in the physical and mechanical properties of bulk materials and the hydrodynamics of the carrier medium, which does not exceed the value determined by the dependence:

where H _lane - the distance between the transverse perforated inserts in height, m; H ₀ - the height of the stationary (filtering) layer of particles of bulk material, m; W is the air flow speed, m / s; W _cr is the critical velocity of fluidization of bulk material, m / s, while maintaining the set value over the entire height of the pipeline, while the distance between the transverse perforated inserts should not exceed 5 diameters of the transport pipeline.

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