RU2723314C1 - Nozzle for vacuuming and aspiration systems - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: disclosed invention relates to cleaning air or gas, as well as their mixtures from mechanical impurities, particularly to trapping and cleaning aspiration air. Nozzle for systems of evacuation and aspiration contains air pipeline, one end of which is made with possibility of its connection with receiving chamber of aspiration unit, and on the other one air receivers are made. Air duct cross-section area and sum of cross-section areas of air receivers are approximately equal to 1:1. Cross-sections of air receivers have different cross-sectional areas to collect air particles of different fractions. Air receivers are detachable. Air receivers are flexible and can change their spatial position. Air pipeline is made cylindrical. Air receivers are arranged at an angle to air duct axis. Air intake with cross-section of larger diameter is located in central part of nozzle, and air receivers with smaller diameters are located in peripheral area of nozzle. Air receivers are equipped with cone-shaped tips.

EFFECT: technical result is higher efficiency of particles removal from working zone.

8 cl, 14 dwg, 3 tbl

Description

The invention relates to the field of purification of air or gas, as well as mixtures thereof from mechanical impurities, in particular to the collection and purification of aspiration air. Aspiration - removal of small particles from the working area by suctioning them with a stream of air (air is used as a carrier medium) into a pipeline through which these particles with a stream of air reach their destination (filter, sump and are collected in any container).

A technical solution is known, including a housing with a ventilation duct and an inlet pipe having an adjustable shutter, a sorting screen, a receiving hopper for large impurities and cleaned particles, additional sorting screens and receiving hoppers with shutters for small impurities and debris [RU 2053030, U1, В07В 7 / 04, 01/27/1996].

The disadvantage of this technical solution is the relatively low quality of separation.

A technical solution is known, comprising a device for loading and supplying a mixture of bulk materials, made in the form of an inlet pipe, a supercharger of air to ensure the flight of particles of a mixture of bulk materials, made in the form of an injection channel, and a returning surface, wherein the device for loading and feeding particles the mixture of bulk materials is made in the form of a slit nozzle in the injection channel, which ensures the creation of disjoint particle paths, and the returning surface is profiled and installed with the possibility of reflection from it and supplying at least part of the flying particles to the receiving bunkers at different angles and with different speeds depending on the properties of the particles [RU 102312, U1, B07B 7/04, 02.27.2011].

The disadvantage of the technical solution is the relatively low quality of separation, since from the return surface only a part of the flying particles of the required size from the mixture of bulk materials is reflected in the receiving hopper.

The closest technical solution is a de-dusting suction unit for air purification, including a vertical collector with radially connected local suction pumps, a dust collector and a fan, in which the local pumps are equipped with pre-screening particles for coarse particles [a.s. USSR No. 967524, IPC B01D 47/00 - prototype].

A disadvantage of the known device is the low level of removal of particles of air pollution in the premises, with large energy and labor costs.

The technical result from the use of the proposed solution can be expressed in the creation of a compact lightweight device that allows for uniform flow of incoming air over a large area without loss of flow velocity and with a decrease in vortex losses, as well as the ability to separate pollution particles into different fractions.

The claimed technical result is achieved as follows.

A nozzle for vacuum and aspiration systems, made in the form of an air duct, one end of which is made with the possibility of its connection with an aspiration unit, and air receivers are made on the other, while the cross-sectional area of the air duct and the sum of the cross-sectional areas of the air receivers are approximately 1: 1.

Moreover, the cross sections of the air inlets have different cross-sectional areas for collecting air pollution particles of various fractions.

The air inlets are predominantly removable and can also be made flexible with the possibility of changing their spatial position.

In addition, the air inlets can be positioned at an angle to the axis of the air duct to reduce height and make the device compact.

In addition, an air inlet with a larger cross-section is located in the central part of the nozzle, and air inlets with smaller diameters are located in the peripheral region of the nozzle.

At the same time, air inlets are equipped with conical tips.

The claimed technical solution is illustrated by the following images.

In FIG. 1 - nozzle, side view, example: a system of pipelines transition from one pipe (1st stage) to 5 (2nd stage), and then to 25 pipes (3rd stage) with the same total cross-sectional area .

In FIG. 2 and 3 are examples of the execution of the “catching plate” nozzle (4th nozzle stage - polygonal bell) - a surface that traps a contaminated gas-air stream using 25 mini-bell holes dispersed over a large area.

In FIG. 4 shows an image of a conventional aspiration cone nozzle with the proposed NOZZLE.

In FIG. 5 A graphical representation of the flow velocity obtained by computational fluid dynamics for a conventional aspiration cone nozzle (left) and the proposed NOZZLE (right).

In FIG. 6, 7, 8, 10 show examples of nozzle design with the central central classical air receiver located in the center of the traditional one and the peripheral air receiver arrangement in the form of tubes with mini-cones.

In FIG. 6, 7, 8, 11, 12, 13, 14 shows an example of a compact "planar" design nozzles.

The low efficiency of the traditional air intake is due to the fact that due to the resistance near the walls and the resulting difference in the flow velocity and the appearance of turbulence, the air flow “drops out” from its edges, reducing its effective particle collection area. When using the claimed technical solution of the nozzle, “dropping out” particles are captured by one or several rows of air receiver tubes with mini-cones. In an advantageous embodiment, air receivers with a smaller cross section than the central air receiver, with cone nozzles, are located in the peripheral region, providing high speed and low air flow turbulence.

The efficiency of removing particles from the working area by their suction method with the air flow used as a carrier medium depends on the following factors:

1. the speed and direction of the initial movement of the particles relative to the receiving hole (s) of the nozzle or pipe;

2. air velocity and volume of transported air in the pipeline;

3. pipeline parameters - diameter, length, the presence of turns and bends and their configuration, surface roughness of the walls of the presence of leaks, etc .;

4. nozzle parameters - configuration, initial and final diameter, wall surface roughness, etc .;

5. remoteness of particles from the edge of the nozzle or pipeline.

To increase efficiency, it is proposed to improve the efficiency of factors 4 and 5.

Despite the fact that the source of the formation of polluting particles in the working area is often quasi-point - a milling cutter, a drill, a grinding or polishing wheel, a paint panel, a nozzle for feeding bulk material into containers, products in a frying pan, grill or frypot during frying, etc. ., however, due to the need to move the moving parts of the equipment, provide access to the tool and the processed material or visual inspection, to organize the screening and capture of polluting particles in the immediate vicinity of the source of their occurrence is often not feasible or economically feasible. To capture polluting particles on a conditional area of one square meter, the performance of an aspiration unit having an inlet pipe with a diameter of about 200 mm (cross-sectional area of 0.03 m ² ) is sufficient. Thus, to capture polluting particles, it is necessary to go from the pipe of the suction unit with a cross-sectional area of 0.03 m ² to capture on an area of 1 m ² - to increase the collection area by tens of times. This is usually achieved using a bell of arbitrary configuration. The result of the use of the bell is the formation of vortices along the walls of the cone, loss of flow rate and absorption efficiency.

The proposed nozzle makes it possible to get as close to the capture zone as possible; a large coverage area is achieved by distributing numerous low-resistance air intakes (degrees 2 and 3 of the nozzle) having smooth walls, smooth bends, and the total cross-sectional area as in the original pipe (nozzle stage 1). The increase in the capture area occurs only at the final stage 4 of the nozzle by means of numerous conical tips. The maximum approach of the air flow to the capture zone and allows you to increase the effective working area of the collection of polluting particles from the nozzle relative to a conventional socket.

Table 1 illustrates the selection of diameters of pipes of the 2nd and 3rd stage (5 and 25 pipes, respectively) of the total similar area to the original pipeline. The increase in area occurs only at the 4th stage at 25 dispersed positions.

Table 2 shows the characteristics of a conventional aspiration cone nozzle.

Table 3 - characteristics of the proposed nozzles.

Claims (8)

1. Nozzle for vacuum and aspiration systems, containing an air duct, one end of which is made with the possibility of its connection with the receiving chamber of the suction unit, and air receivers are made on the other, while the cross-sectional area of the air duct and the sum of the cross-sectional areas of the air receivers are approximately 1: 1 . 2. The nozzle according to claim 1, in which the cross sections of the air inlets have different cross-sectional areas for collecting air pollution particles of various fractions. 3. The nozzle according to claim 1, in which the air intakes are removable. 4. The nozzle according to claim 1, in which the air inlets are made flexible with the possibility of changing their spatial position. 5. The nozzle according to claim 1, in which the air duct is cylindrical. 6. The nozzle according to claim 1, in which the air inlets are located at an angle to the axis of the air duct. 7. The nozzle according to claim 1, in which an air inlet with a larger cross-section is located in the central part of the nozzle, and air inlets with smaller diameters are located in the peripheral region of the nozzle. 8. The nozzle according to claim 1, in which the air inlets are equipped with conical tips.

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