RU88109U1 - DEFLECTOR - Google Patents

Abstract

1. Ventilation system deflector mounted on a ventilation riser pipe, containing three conical disks with the same outer diameter and taper angle, connected to each other by racks, the two upper disks face each other with small bases to form a channel along the Venturi profile, the lower one a disc mounted on the riser pipe and a protective mesh placed inside the deflector, characterized in that a plate collector with drainage drainage tubes is attached to the small base of the upper conical disc, and a drop catcher is made in the lower part of the riser pipe, containing a nipple with an internal flare, telescopically entering inside the pipe, and drainage holes made in the pipe at the level of the nipple flange. ! 2. The deflector according to claim 1, characterized in that the nipple is installed on the pipe on the sealant by means of a rivet joint. ! 3. The deflector according to claim 1, characterized in that the flange of the nipple is made conical. ! 4. The deflector according to claim 1, characterized in that the poppet collector is mounted on a conical disk by means of a rivet connection, and the drainage drainage tubes are made of a non-metallic material, such as polyethylene.

Description

The proposed utility model is designed for exhaust natural ventilation systems and can be used both for ventilation systems of residential and administrative buildings, and for ventilation systems of industrial buildings for any purpose.

Known deflector mounted on the ventilation riser and containing mounted on the riser and fastened to each other radial partitions, as well as attached to the last different-sized conical rings, while these rings are displaced relative to each other along the axis of the deflector with the formation between them of confuser channels for the passage of external air, ejecting contaminated air from the ventilation riser (USSR Author's Certificate No. 1788395, IPC ⁵ F24F 7/02).

However, the known deflector does not provide effective removal of contaminated air, since it is actually an ejector, the coefficient of action of which is low.

Also known is a deflector mounted on a vertical ventilation riser and comprising three conical disks of complex shape interconnected by vertical racks, two of which are truncated, offset relative to each other along the axis of the deflector and facing small bases towards each other with the formation of a channel with a Venturi nozzle profile for outdoor passage and removal of contaminated air removed from the room. The lower disk adjacent to the ventilation riser is flanged toward the upper and the central hole having a diameter equal to the diameter of the opening of the ventilation riser. The third conical disk is located above the upper disk. A protective net is installed between the disks and in the spacer between them (Application for invention No. 98109351 A, IPC ⁷ F24F 7/00, publ. 2000).

However, this known deflector is expensive because aluminum, non-ferrous aluminum, and stainless steel are used for its manufacture. In addition, conical disks have different taper angles and a complex shape, since each sectional disk consists of two truncated conical disks conjugated to each other, manufactured either by stamping or by deep drawing, and they are forced to use a whole set of tools when assembling the deflector, and all this leads to a rise in the cost of the deflector.

A ventilation system deflector mounted on a vent pipe is also known, containing three conical disks with the same outer diameter and taper angle, connected to each other by uprights, the two upper disks facing each other with small bases to form a channel along the Venturi profile, the lower a disk mounted on the riser pipe, and a protective grid placed inside the deflector (Certificate for a utility model of the Russian Federation No. 24722, IPC 7 F24F 7/00, published on 08/20/2002).

This technical solution is a prototype of the proposed utility model.

The disadvantage of the prototype, as well as the above analogues, is the leakage of rain water into the ventilation riser during heavy rains and rains with strong winds. Water penetrates into the horizontal sections of the ducts, which leads to leaks, damage to the ceiling and walls, to the formation of foci of microflora and unpleasant odors inside the ventilation system. As observations have shown, there are two main ways for water to enter the riser:

A) on the surface of the upper truncated cone and further into the deflector pipe, and from it into the riser;

B) directly to the windward side of the deflector pipe, and from it to the riser.

The technical task of the present invention is to change the design of the device, which allows to overcome these disadvantages of the prototype.

The technical result is the creation of a deflector having a simple design with high reliability and preventing the penetration of moisture into the ducts.

The task and the necessary technical result are achieved by the fact that in the known vent of the ventilation system mounted on the ventilation pipe of the riser, containing three conical discs with the same outer diameter and taper angle, connected to each other by uprights, two upper disks facing each other to each other with small bases with the formation of a channel along the Venturi profile, the lower disk mounted on the riser pipe, and a protective grid placed inside the deflector, to the small base of the upper conical disk The dish-shaped water collector with drainage drainage pipes is insulated. In the lower part of the riser pipe, a droplet eliminator is made, containing a nipple with an internal flange, telescopically entering the pipe, and drainage holes made in the pipe at the flange level of the nipple. The nipple can be mounted on the pipe on the sealant through a rivet connection. The flange of the nipple may be conical. A poppet collector can be mounted on a conical disk by means of a rivet connection, and drainage drainage pipes are made of non-metallic material, for example, polyethylene.

The essence of the utility model is illustrated by drawings, where:

figure 1 in a section schematically shows the proposed model of the deflector;

figure 2 - node a in figure 1 on an enlarged scale;

figure 3 - node B in figure 1 on an enlarged scale;

The deflector mounted on the ventilation riser contains three conical disks 1, 2 and 3 of simple shape, of the same outer diameter and with the same taper angle of about 30 degrees. Two discs 1 and 2 are truncated and offset along the axis 4 of the deflector relative to each other. Disks 1 and 2 face each other with small bases 5 and 6 with the formation of a channel 7 between them along the profile of the Venturi nozzle for the passage of external and exhaust air removed from the room. The disk 1 is made with a Central hole 8, the diameter of which is equal to the diameter of the pipe in the ventilation riser. The ratio of the distance "h" between the small bases 5 and 6 of the disks 1 and 2 to the diameter "d" of the central hole in the disk 1 is from 0.3 to 0.4. Disk 3 is mounted above disk 2 and connected to it by a large base. To prevent foreign objects and birds from entering the channel 7, a grid 9 is installed, while the disks 1, 2, 3 are jointly connected by the uprights 10, and the net 9 is also attached to the latter. A pipe 11 is attached to the disk from the side of the ventilation riser, by means of which a deflector is installed On him. All deflector disks and pipe 11 are made of galvanized steel.

Figure 2 shows an enlarged view of the device of a poppet collector with drainage drainage pipes. The plate water collector 12 is fastened with rivets 13 to the upper truncated conical disk 2. In the bottom of the disk water collector 12 in several places there are evenly arranged nipples 14 to which hoses 15 are connected, for example, of polyethylene. Drainage drainage tubes 15 (hoses made of polyethylene or rubber) are attached with their free ends to the risers 10, for example, using plastic clamps.

Figure 3 shows in an enlarged view a droplet eliminator consisting of a nipple 16, which telescopically enters the pipe 11 and fastens to it through the sealant 17 with rivets 18. The nipple 16 has a flange 19, for example, conical, at the level of which several holes 20 are made in the pipe 11 evenly spaced around the circumference. These holes 20 are designed to drain water entering in the form of drops 21 into the riser pipe.

The utility model works as follows.

In the absence of wind, the removal of polluted air from the room is carried out according to the principle of natural gravitational ventilation due to the different densities of polluted (used) indoor air and outdoor air. During rain, in the absence of wind, raindrops cannot penetrate the riser due to the presence of a protective disk 3.

In the presence of wind, the utility model provides increased thrust due to channel 7, in which, in accordance with the Bernoulli equation, the pressure decreases, which, in turn, leads to a more complete removal of contaminated air from the room and provides the latter with higher air quality.

In the presence of strong wind and rain, water droplets fall on the surface of disk 2 and, under the influence of wind and gravity, flow down its windward surface, accumulating in a poppet collector 12, from which rainwater flows through the nozzle 14 and hoses 15 to the disk 1 and then to a roof (not shown).

At the same time, along with the wind, raindrops fall into channel 7, and some of them, under the influence of gravity and turbulence of the flow, can fall on the inner windward surface of the pipe 11. These drops 21, flowing down, fall into the annular pocket formed by the pipe 11 and flanging 19 of the nipple 16, from which rainwater flows through the openings 20 to the roof (not shown).

The tests of the deflector showed its effectiveness, which indicates its industrial applicability of the utility model.

Claims (4)

1. The vent of the ventilation system mounted on the pipe of the ventilation riser, containing three conical disks with the same outer diameter and taper angle, connected to each other by uprights, the two upper disks facing each other with small bases to form a channel along the Venturi profile, lower a disk mounted on the riser pipe and a protective net located inside the deflector, characterized in that a poppet with drainage pipes is attached to the small base of the upper conical disk, and In the lower part of the riser pipe, a droplet eliminator is made, containing a nipple with an internal flange, telescopically entering the pipe, and drainage holes made in the pipe at the flange level of the nipple. 2. The deflector according to claim 1, characterized in that the nipple is mounted on the pipe on the sealant by means of a rivet connection. 3. The deflector according to claim 1, characterized in that the flanging of the nipple is made conical. 4. The deflector according to claim 1, characterized in that the poppet is mounted on a conical disk by means of a rivet connection, and the drainage drainage pipes are made of non-metallic material, such as polyethylene.