RU2096692C1 - Exhaust hood - Google Patents

Abstract

FIELD: ventilation; evacuation and processing foul air in close proximity to source of its formation. SUBSTANCE: exhaust hood (cabin shelter) has housing with working aperture in front hollow wall connected with air duct, partition located in housing and provided with holes forming exhaust passage together with rear wall; this passage is filled with filter material and is connected to autonomous suction. Inlet holes in working aperture have manifold inlets. EFFECT: enhanced efficiency. 2 cl, 2 dwg

Description

 The invention relates to ventilation and can be used to remove harmful substances, treat (clean) the removed air in the immediate vicinity of the source of their formation, followed by transporting cleaner air.

Known fume hoods and cabin shelters that trap harmful emissions formed in various technological processes [1]
However, the described devices are characterized by an uneven absorption spectrum in the working opening, which leads either to an overestimation of the amount of air removed, or to inefficient capture, and sometimes to both at the same time.

The closest technical solution to the claimed technical essence and the achieved effect is a fume hood containing a housing with a working opening in the front wall, a partition with openings located in the housing, forming an exhaust channel with its rear wall connected to the duct, the front wall is hollow and connected also to the duct [2]
However, this device is characterized by a significant amount of exhaust air due to the creation of a significant vacuum in the cavity of the inner case, the presence of movable elements and a significant consumption of materials.

 The present invention will achieve a technical result, expressed in increasing the efficiency and reliability of a fume hood (cabin cover), significantly reducing the most polluted part of the removed air in a quantitative sense and treating this polluted air near its source by passing through a filter material through an autonomous suction system.

 The technical result is achieved in that in a fume hood (cabin shelter) comprising a housing with a working opening in the front hollow wall connected to the air duct, a partition with holes located in the housing forming an exhaust duct with its rear wall, the exhaust duct from the back wall side is filled filtering material, for example bulk, and is connected to an autonomous suction, and the inlets in the working opening have collector inputs.

 The proposed technical solution allows you to create a uniform absorption spectrum both in the outer wall of the working opening and in the inner one, because the inlets in the working opening have collector entrances, while the main part of the incoming air will play the role of an aerodynamic shutter, preventing the knockout of the most polluted part of the air formed in the process. Autonomous suction from the fume hood cavity, where the technological process takes place, creates a calculated vacuum in this cavity, which will prevent the contaminated air from blowing out, and the air removed by this suction will be cleaned on filter material, for example, in a bulk filter located in the exhaust channel from the back side fume hood walls.

 In FIG. 1 shows a section through the device, and in FIG. 2 general view in plan.

 A fume hood (cabin cover) contains a housing 1, a working opening with collector inputs 2 and 3 in the front hollow wall 4, a local suction 5 connected to the front hollow wall 4, a hopper for bulk material 6, an autonomous local suction 7, a partition with holes ( louvered partition) 8, forming with the rear wall of the fume hood an exhaust channel connected to an autonomous local suction 7, filter material (for example, bulk) 9, an inclined plate 10, a gate 11, a container for bulk material 12.

 A fume hood operates as follows.

 Through the collector inlet 2 of the working opening, the outside air enters the local suction 5, the partially polluted air from the fume hood cavity also enters there through the collector inlet 3 of the working opening. Since the outside air enters at a uniform speed, it is an effective aerodynamic shutter and eliminates the outflow of contaminated air. Part of the external air through the collector inlet 3 of the working opening enters the cavity of the fume hood, where the process takes place, is contaminated and, by means of an autonomous local suction 7, after being cleaned on the filter material 9, is removed into the general ventilation system. If the filter material is contaminated, it is replaced. For example, in the case of using bulk filtering material, it, the material, is periodically replenished through (from) the hopper 6 and the contaminated material is removed through the opening through the gate 1 into the container 12. Due to the fact that by means of autonomous suction it is possible to maintain minimal vacuum in the cavity of the fume hood (cabin shelter) where the technological process takes place, the amount of air removed by this suction will be minimal, which means that significant emission of harmful substances from the technological process itself is excluded cessa.

 The proposed technical device will significantly reduce the consumption of air being removed, and the most contaminated part of it should be treated (cleaned) in the immediate vicinity of the place of its formation. The inlets in the working opening have collector inputs. This ensures a uniform velocity field, which significantly reduces the removal of harmful substances from the cabinet and reduces the flow of suction air.

 The proposed device can be used in spray booths, for example, in the manufacture of enameled glassware, painting parts, in laboratory fume hoods, etc.

Claims (2)

 1. An exhaust hood comprising a housing with a working opening in a front hollow wall connected to an air duct, a partition with holes located in the housing, forming an exhaust channel with its rear wall, characterized in that the exhaust channel on the back wall side is filled with filter material, for example, bulk , and is connected to an autonomous suction, and the inlets in the working opening have collector inputs.  2. The cabinet according to claim 1, characterized in that the exhaust channel from the rear wall is equipped with a loading hopper and a container for unloading bulk material.

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