RU2428635C2 - Procedure for local exaust ventilation and device for its implementation - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: peripheral jet of incoming air is generated in form of swirled circular jet; also symmetry axis of peripheral jet is matched with symmetry axis of suction branch. Flow of air in the peripheral jet is oriented so, that projection of this flow rate to symmetry axis is directed opposite to direction of a sucked flow. Characteristic diametre of the generated periphery jet exceeds diametre of the sucked jet at inlet into the suction branch not less, than five times. One end of the device case is open, while another one - closed. The device is equipped with a plate positioned inside the case parallel to the closed end. In the plate and in the open end there are coaxial orifices facilitating passage of the suction branch through them without a gap. The plate is set with a gap to side walls of the case. Between the plate and the closed end there is formed an inlet channels for supply of purified air and for generation of the periphery jet. The device is equipped with an appliance for swirling the periphery jet installed inside the inlet channel.

EFFECT: improved work environment and safety measures.

10 cl, 3 dwg

Description

The invention relates to ventilation and cleaning technology and can be used for local remote removal of fine and molecular air pollution, such as harmful gases, fine aerosol, etc., formed, in particular, during welding, soldering, in galvanic production, etc.

There are various methods of ventilation and ventilation of rooms and other objects: USSR No. 712509 (1980) [1], RF patent No. 2232353 (2003) [2] and others. Known, for example, by A.S. USSR No. 1566172 (1990) [3] the method of ventilation of the premises by tangential air injection and its simultaneous suction from the central zone to obtain a vortex air flow. However, this method is suitable for ventilation of the entire room and is not suitable for local ventilation of a separate workplace in a large room.

There are various devices for ventilation and cleaning: USSR No. 567035 (1977) [4], A.S. USSR No. 1525418 (1989) [5], RF patent No. 2354891 (2009) [6], etc. It is known, for example, by A.S. USSR No. 1542544 (1990) [7] a blowing-in nozzle containing a snail swirl and a suction pipe coaxially mounted in it, in which the supply air enters the snail swirl and, passing between its walls and a guide made in the form of a truncated cone, forms an annular open, strongly swirling jet. However, the diameter of the annular jet is close in magnitude to the diameter of the suction nozzle, therefore, its interaction with the upward axial flow leads to instability of the flow, as a result of which there is an emission of contaminants from the suction upward jet into the surrounding space.

The closest in technical essence to the claimed method is a method of local exhaust ventilation according to the patent of the Russian Federation No. 2046258 (1995) [8], adopted as a prototype.

The closest in technical essence to the claimed device is a local exhaust ventilation device according to the patent of the Russian Federation No. 2046258 (1995) [8], adopted as a prototype.

There is a method of local exhaust ventilation [8] by suction from the zone of harmful emissions of air polluted by them, the formation of suction air into the central torch, the formation of the supply air stream in the form of an open radial fan stream, set the flow rate of the suction air Q ₀ , determine the flow rate of the supply air Q _p from the relationship Q _p = αQ ₀ , 0.6 <α <1.1.

However, the known method is characterized by insufficient efficiency and functionality.

A device for local exhaust ventilation [8], containing a cylindrical body with a coaxially placed suction pipe in it, having a receiving hole on the cut, located between the body and the pipe, a peripheral flow swirl. The housing has a diffuser, coupled with it and located at the cut-off level of the suction pipe from the side of its inlet. In this case, the walls of the diffuser have a bend with a radius of curvature R _d = γR _k , R _k - the radius of the body, 0.3 <γ <1.3 the coefficient of shape of the bend.

However, the known device is characterized by a lack of efficiency and functionality. The spread of the swirling jet in the radial direction reduces the range of the suction torch. As a result, the distance from the cut of the device to the capture area of the removed contaminated air does not exceed 6-7.5 diameters of the suction pipe. However, such a distance is not enough in various technological industries for given sizes of ventilation pipes.

Thus, the disadvantages of the known method and device are insufficient efficiency and functionality.

The problem to which the invention is directed, is to increase the efficiency and expand the functionality of the local exhaust ventilation method and device for its implementation.

To solve this problem, the essence of the proposed method is that, in contrast to the known method of local exhaust ventilation, including suction from the area of air pollution, the formation of suction air into the central suction torch, the supply of fresh air, its formation in a swirling peripheral stream, shielding the central the torch according to the invention, the peripheral stream (peripheral stream) of the supply air is formed in the form of a swirling ring stream. In this case, the symmetry axis of the peripheral jet is combined with the symmetry axis of the suction jet (i.e., with the symmetry axis of the suction pipe). The air flow in the peripheral stream is directed (oriented) so that the projection of the velocity of this flow on the axis of symmetry is directed opposite to the direction of the suction stream. In this case, the peripheral jet is formed in such a way that its characteristic diameter exceeds the diameter of the suction jet at the inlet to the suction pipe by at least five times.

In addition, the suction air is passed through a filter, for example, fine cleaning, and the purified air is fed (returned) into the supply air stream (into the inlet channel of the device).

Also, to solve the problem, the essence of the device for implementing the proposed method consists in the fact that, in contrast to the known device for local exhaust ventilation, including a cylindrical body with a suction pipe coaxially placed therein, having a receiving hole, a swirl of the input peripheral stream, according to the invention, one the end face of the housing is open, the second end is closed, and the device is equipped with a plate that is located inside the housing parallel to the closed end. In this plate and the closed end there are coaxial holes for the passage of the suction pipe without a gap with them (thus, the suction pipe is located in the above coaxial holes without a gap with them). The plate is installed with a gap with the side walls of the housing, and an inlet channel is formed between the plate and the closed end for supplying purified air and forming a peripheral stream (peripheral stream). The device is also equipped with a means for swirling the peripheral stream (peripheral stream). Said peripheral flow swirl means is installed inside the input channel. In the closed end there are holes for supplying purified air located between the swirl and the suction pipe, while the inner diameter of the housing D ₀ and the diameter of the intake hole of the suction pipe D ₁ are related by the ratio: D ₀ > 5 · D ₁ .

In addition, the device is equipped with a pipeline through which suction air is removed, and in which a fine filter is installed, and after said filter, the pipeline is connected to the input channel of the device, i.e. the pipeline outlet is connected to the input channel of the device.

In addition, the open end of the housing is equipped with a diffuser, the inner surface of which smoothly (without the formation of corners or kinks) is interfaced with the inner surface of the housing, while the diameter of the outlet of the diffuser D ₂ and the diameter of the inlet of the suction pipe D ₁ are connected by the ratio: D ₂ > 5 · D ₁ .

In addition, said plate is made, for example, round.

It is the claimed design differences, the features of the device for local exhaust ventilation, that allow to implement the inventive method, thereby ensuring the achievement of the task, which allows us to conclude that the claimed invention are interconnected by a single inventive concept.

The technical result that can be obtained by using the inventions is to increase the efficiency and expand the functionality of the local exhaust ventilation method and device for its implementation.

The invention is illustrated by drawings:

Figure 1 shows the device in axial section; figure 2 - a device equipped with a fine filter; figure 3 - device with a diffuser.

The device contains a cylindrical body 1, one end of which is open, the other is closed, a plate 2 located parallel to the ends, a suction pipe 3, an inlet channel 4, means for twisting the peripheral flow 5, openings for supplying purified air 6, a pipeline for pumping out suction air 7, a filter fine cleaning 8, diffuser 9.

The device operates as follows.

Air is taken in through the suction pipe 3. The cleaned air enters through the openings 6, moves through the channel 4, passes through the swirling means 5 and acquires a pulse moment relative to the axis of the suction pipe 3. The swirling air enters the gap between the plate 2 and the side walls of the housing 1 and moves further along the side walls in the form of a swirling wall jet. Reaching the open end of the housing 1, it flows into the open space in the form of a flooded annular swirling jet. The jet extends up to the surface near which the area of contaminated air is located. Part of the annular jet is drawn into the suction jet. In this case, the suction jet spins up, and a vortex flow is formed, resembling the movement of air in natural tornadoes. As a result, contamination is collected from distances from the cut of the open end of the housing, tens of times larger than the diameter of the suction pipe. In the absence of a vortex, the fence becomes ineffective, since there is no localization of the air flow velocities inside the core of the vortex, which leads to a significant decrease in the flow velocities and thereby a decrease in the ejection ability of the suction jet. Using an additional fine filter in the suction channel of the device and returning the cleaned air to its inlet channel will simplify the ventilation scheme and avoid the loss of adjusting the temperature regime of clean air when it is taken from the atmosphere outside the building.

When a flow structure is formed with a peripheral swirling ring jet, the diameter of which is not less than 5 times the diameter of the suction pipe, the development of instability associated with the interaction of the peripheral jet and the suction flow is excluded. At the same time, part of the swirling peripheral flow is drawn into the suction jet, which, in turn, leads to its swirling and the formation of a vortex flow. Near the axis, which is a continuation of the axis of the suction pipe, an area called the vortex core is formed, similar in shape to a cylindrical one, inside of which there is intense axial movement of air around the axis towards the suction pipe. The core of the vortex extends in length up to the surface from which the contaminants are removed, opposite to the suction pipe, its diameter does not exceed the diameter of the suction pipe. The flow velocities are localized inside the nucleus and vary little along its entire length. In this case, the diameter of the suction region on the surface does not exceed 3-4 core diameters, at the same time, the length of the core of the vortex, within which the air removed from the air pollution zone is transferred, can reach several tens of its diameters. Thus, the remote removal of contaminants from a localized area, including from a surface remote from the cut of the device, is carried out at a distance tens of times greater than the diameter of the suction port, which makes the method more efficient than known methods that allow the removal of contaminants from distances exceeding 6-7.5 diameters.

The experiments show great efficiency and wide functionality of the proposed method and device. So, for example, a study of the removal of smoke from a localized pollution source located on a flat surface by the vortex flow generated by the proposed method was carried out with the following parameters of the model installation: diameter of the suction pipe 28 mm, case diameter 500 mm, volumetric flow rate for suction was approximately 10 ³ cm ³ / s, total flow rate -

2 · 10 ³ cm ³ / s. Smoke was supplied through an opening in a plane with a diameter of 6 mm at a speed of approximately 5 m / s and was scattered along the plane by a deflector (plate with a diameter of 2 cm) mounted above the hole at a distance of 1 cm. With a proper choice of swirl, a vortex arose and smoke was removed from a surface remote from the open cut of the housing by a distance reaching 700 mm. The diameter of the capture region did not exceed 100 mm. Thus, the capture area was localized, no smoke was released into the surrounding atmosphere, and the area was removed by 25 diameters of the suction pipe from the open cut of the housing. In the absence of a peripheral stream or its swirl, the incoming smoke was scattered into the surrounding atmosphere, and only a part of it went into the suction. At the same time, the suction flow rate doubled.

Thus, the use of inventions can significantly increase the efficiency and expand the functionality of the method of local exhaust ventilation and device for its implementation. For example, they can be used to quickly and efficiently remove contaminants resulting from accidents or intentional acts. In addition, the use of the invention will significantly improve working conditions and safety.

Bibliography:

1. A.S. USSR No. 712509 (1980).

2. RF patent No. 2232353 (2003).

3. A.S. USSR No. 1566172 (1990).

4. A.S. USSR No. 567035 (1977).

5. A.S. USSR No. 1525418 (1989).

6. RF patent No. 2354891 (2009).

7. A.S. USSR No. 1542544 (1990).

8. RF patent No. 2046258 (1995).

Claims (10)

1. The method of local exhaust ventilation, including the formation of suction air into the central suction torch, the supply of fresh air, its formation in a swirling peripheral stream, characterized in that the peripheral stream (peripheral jet) of the supply air is formed in the form of a swirling circular jet, the axis of symmetry of the peripheral jet combine with the axis of symmetry of the suction jet, and the air flow in the peripheral jet is directed (oriented) so that the projection of the velocity of this flow on the axis of symmetry is directed against opolozhno direction intake flow, wherein a peripheral jet is formed such that its diameter is greater than the characteristic diameter of the jet inlet sucked into the suction pipe is not less than five times. 2. The method according to claim 1, characterized in that the suction air is passed through a filter, for example, fine cleaning, and the purified air is fed (returned) to the supply air stream. 3. A device for local exhaust ventilation, comprising a cylindrical body with a suction nozzle coaxially placed therein, having a receiving hole, a swirl of the input peripheral stream, characterized in that one end of the body is open, the second end is closed, the device is equipped with a plate that is located inside of the housing parallel to the closed end, in the plate and the closed end there are coaxial holes for the passage of the suction pipe without a gap with them, i.e. the suction pipe is located in the above-mentioned coaxial openings without a gap with them, while the plate is installed with a gap with the side walls of the housing, and between the plate and the closed end there is an inlet channel for supplying purified air and forming a peripheral stream (peripheral stream), while the device is equipped with means of twisting the peripheral stream (peripheral stream), which is installed inside the inlet channel, in addition, in the closed end there are holes for supplying purified air located between dstvom twist and the suction pipe, wherein the inner diameter of the housing and the diameter D ₀ of the reception opening of the suction pipe connected by the relation D _1: D _0> 5 · D _1. 4. The device according to claim 3, characterized in that it is provided with a pipeline through which suction air is removed and in which a fine filter is installed, and after said filter, the pipeline is connected to the input channel of the device. 5. The device according to claim 3, characterized in that the open end of the housing is equipped with a diffuser, the inner surface of which smoothly (without the formation of corners or kinks) is interfaced with the inner surface of the housing, while the diameter of the outlet of the diffuser D ₂ and the diameter of the inlet of the suction pipe D ₁ are related by the relation: D ₂ > 5 · D ₁ . 6. The device according to claim 4, characterized in that the open end of the housing is equipped with a diffuser, the inner surface of which smoothly (without the formation of corners or kinks) is interfaced with the inner surface of the housing, while the diameter of the outlet of the diffuser D ₂ and the diameter of the inlet of the suction pipe D ₁ are related by the relation: D ₂ > 5 · D ₁ . 7. The device according to claim 3, characterized in that the plate has the shape of, for example, a circle. 8. The device according to claim 4, characterized in that the plate has the shape of, for example, a circle. 9. The device according to claim 5, characterized in that the plate has the shape of, for example, a circle. 10. The device according to claim 6, characterized in that the plate has the shape of, for example, a circle.

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