KR20120076996A - Damper structure for exhaust pipe connected to vertical ventilating duct - Google Patents

Abstract

PURPOSE: A damper structure for an exhaust pipe connected to a vertical ventilation duct is provided to prevent exhaust gas from flowing backward to a damper when the damper is opened and to efficiently ventilate an indoor space. CONSTITUTION: A damper structure for an exhaust pipe connected to a vertical ventilation duct comprises a damper housing(10) and damper plates(LD,FD). The damper housing is connected to a ventilation duct and has an internal air passage. The damper plates are rotatably installed through a rotary shaft(H) located under the inner center shaft of the damper housing and open and close a part of the air passage through rotation. The damper plate located at the bottom restricts the rotation angle of the damper plates.

Description

Damper structure for exhaust pipe connected to vertical ventilating duct}

The present invention relates to a damper structure on a vertical exhaust pipe connected to a granular ventilation duct formed in a vertical direction in a multi-family house or a building. In particular, the exhaust gas of the lower floor discharged through a vertical risen ventilation duct of an apartment or a public house or other building is The present invention relates to a damper structure on an exhaust pipe connected to a vertical upright ventilation duct for preventing the inflow of the backflow and opening the indoor air of the main floor smoothly while opening the dumper to vent the actual air of the main floor.

In general, in apartments, multi-family furniture and other buildings there is provided a duct for ventilating the odor, polluted air generated in the room, such as the kitchen or bathroom inside to the outside.

To this end, the ventilation passage duct granular in a vertical direction is typically set in a construction passage of a multi-layered building, and as shown in FIG. 1, the vertical ventilation duct of a granular type in a vertical direction is set in the construction passage of the building. ) Is installed, a separate saddle (4) is installed on the side of the vertical ventilation duct (1) is formed to be coupled to the flexible duct (3) of the kitchen or bathroom side for each floor.

And the perforated plate 5 for exhaust is installed on the uppermost layer of the vertical ventilation duct 1, while the exhaust fan 6 is installed on the upper part of the perforated plate 5 to take a structure formed to exhaust the collected polluted air into the atmosphere. have.

However, in the conventional structure, since the coupling of the vertical ventilation duct 1 and the flexible duct 3 is vertically coupled to each other, the following problems are caused.

That is, the air guided from the flexible duct 3 of the upper layer to the vertical ventilation duct 1 in the process of being guided onto the vertical ventilation duct 1 from the lower flexible duct 3 and exhausted to the upper layer is interfering with each other. As a result, a phenomenon that disturbs the smooth flow occurs.

As such, when interference occurs between the air flows between the layers, not only smooth exhaust of the polluted air is performed but also there is a concern that the polluted air of another layer is introduced.

In order to solve such a problem, it is conventionally proposed that the vertical ventilation duct 1 has a spiral rib on its inner surface to increase ventilation through a kind of twisting effect, but it is insufficient as a fundamental solution.

In addition, it has been proposed to suppress the interference between the air flows generated when the vertical ventilation duct 1 and the flexible duct 3 is coupled vertically by giving a predetermined eccentricity, but also as described above, The solution was insufficient.

On the other hand, it is proposed that a damper is provided between the conventional flexible duct 3 and the vertical ventilation duct 1 to block the inflow of odor and polluted air generated in the kitchen or bathroom of the adjacent floor.

However, even if the above-mentioned damper is applied, as shown in the accompanying FIG. 2, even if the actual damper is applied, in terms of fluid dynamics, there is no problem in the closed state of the damper, but when the damper is opened to discharge gas, the flexible duct Exhaust gas discharged from (3) flows upwards due to the flow of air exhausted through the vertical ventilation duct (1), resulting in vortex shape and backflow phenomenon.

Furthermore, the reverse flow phenomenon rather than the vortex phenomenon remains in the flexible duct 3 when the damper is switched to the closed state, which is a practical problem because it flows back into the room.

An object of the present invention for solving the above problems relates to a damper structure on the vertical exhaust pipe connected to the granular ventilation duct formed in the vertical direction in a multi-family house or building, in particular, the vertical rise ventilation duct of an apartment or public housing or other buildings When the exhaust gas of the lower floor discharged through the dumper is opened to vent the actual air of the main floor, the exhaust pipe is connected to the vertical riser duct connected to the vertical granular ventilation duct so as to prevent the inflow and inflow of the main floor. To provide a damper structure.

The characteristic of the damper structure on the exhaust pipe connected to the vertical granular ventilation duct according to the present invention for achieving the above object, the damper structure on the vertical exhaust pipe connected to the granular ventilation duct formed in the vertical direction in the apartment house or building. A damper housing connected to the granular ventilation duct and having an air passage therein; A damper plate installed in the damper housing so as to be rotatable via a rotation shaft positioned below the central shaft, and configured to open and close a portion of the air passage of the damper housing according to the rotation thereof; The damper plate located below the damper plate positioned above the rotary shaft in the state connected to the granular ventilation duct has a heavy weight to limit the rotation angle rotated by the rotary shaft and simultaneously rotate In operation, by rapidly returning by its own weight, it is to block the exhaust gas flowing back through the granular ventilation duct.

An additional feature of the damper structure on the exhaust pipe connected to the vertical standing ventilation duct according to the present invention for achieving the above object is a seal for increasing airtightness when the air passage is closed through the light damper plate and the heavy damper plate. A ring member is formed in the damper housing.

An additional feature of the damper structure on the exhaust pipe connected to the vertical upright ventilation duct according to the present invention for achieving the above object is that the one side of the air passage of the damper housing is connected to the granular ventilation duct. It is to form a wing piece for preventing the exhaust gas discharged through the ventilation duct flows into the air passage of the damper housing.

As expected effects due to the above-described features of the present invention, when the exhaust gas of the lower floor discharged through the vertical riser ventilation duct of an apartment, a public house, or other building opens the dumper to vent the actual air of the main floor, While preventing the inflow, it is possible to smoothly ventilate the indoor air of the main floor.

1 is a conceptual view showing an installation structure of a duct formed of a conventional synthetic resin
Figure 2 is an exemplary view for explaining the flow of the exhaust gas according to the operation when the conventional damper mounted on the exhaust pipe connected to the vertical riser ventilation duct
Figure 3 is an exemplary cross-sectional view for explaining the damper structure on the exhaust pipe connected to the vertical riser ventilation duct according to the present invention
4 is an exemplary view for explaining the flow of exhaust gas according to the damper operation shown in FIG.
5 is a cross-sectional view illustrating a state in which an additional non-return wing piece is added to a damper structure on an exhaust pipe connected to a vertical riser ventilation duct according to the present invention shown in FIG. 3.

The above object and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a cross-sectional view illustrating a damper structure on an exhaust pipe connected to a vertical riser ventilation duct according to the present invention, and FIG. 4 is a view illustrating the flow of exhaust gas according to the damper operation shown in FIG. 3. FIG. 5 is a cross-sectional view illustrating a state in which an additional backflow prevention wing piece is added to a damper structure on an exhaust pipe connected to a vertical riser ventilation duct according to the present invention shown in FIG. 3.

As shown in the accompanying drawings, the damper on the exhaust pipe connected to the vertical standing ventilation duct according to the present invention has a specific cross-sectional shape inside the damper housing 10 connecting the flexible duct 3 and the vertical ventilation duct 1. It is formed on the air passage having.

At this time, looking at the structure of the damper for opening and closing the air passage, the damper housing 10 is installed to be rotatable through the rotation shaft (H) located below the central shaft in the damper housing 10 according to the rotation of the damper housing (10) Damper plates (LD, FD) for opening and closing a portion of the air passage of the; The damper plate (FD) located below the damper plate (LD) located above the rotary shaft (H) in the state connected to the granular ventilation duct is formed to have a heavy weight of the rotary shaft (H) By limiting the rotation angle by the rotation and at the same time by the rapid recovery by its own weight during the recirculation operation to block the exhaust gas flowing back through the granular ventilation duct, the light damper plate (LD) and heavy damper plate (FD) It is composed of a sealing member (S) for increasing the airtightness when the air passage is closed through).

Furthermore, as shown in FIG. 5 additionally attached, the air exhaust of the damper housing 10 connected to the granular ventilation duct 1 is discharged through the granular ventilation duct 1 to the outside once. A wing piece SP is formed to prevent gas from flowing into the air passage of the damper housing 10.

In this case, reference numeral 11 is a stepped limit for setting the connection position of the flexible duct 3 and the vertical ventilation duct 1 is formed on the outside of the damper housing (10).

Therefore, the heavy damper plate (FD) is located in the lower position and the light damper plate (LD) is located in the upper state in the state connected to the granular ventilation duct (1) through the above-described structure to make the granular ventilation duct (1) It is to block the exhaust gas flowing back through.

In addition, the hinge shaft (H), as shown, it is preferable to be located below the central passage of the air passage of the damper housing 10.

In addition, the wing piece (SP), in addition to the function of preventing the backflow, when the light damper plate (LD) is operated to exhaust the exhaust gas discharged through the flexible duct 3, the exhaust gas exiting vertically, that is, granular ventilation It serves as a kind of guide piece to guide in the same direction as the flow direction of air discharged through the duct (1).

While the invention has been shown and described with respect to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone with it will know easily.

10: damper housing
LD: Light damper plate
H: axis of rotation
FD: Heavy Damper Plate
S: sealing member
SP: wing

Claims (3)

In a damper structure on a vertical exhaust pipe connected to a granular ventilation duct formed in a vertical direction in an apartment or building:
A damper housing 10 connected to the granular ventilation duct and having an air passage therein;
A damper plate (LD) installed rotatably through a rotation shaft (H) positioned below the central axis in the damper housing (10) to open and close a portion of the air passage of the damper housing (10) according to the rotation thereof. FD);
The damper plate (FD) located below the damper plate (LD) located above the rotary shaft (H) in the state connected to the granular ventilation duct is formed to have a heavy weight of the rotary shaft (H) The damper on the exhaust pipe connected to the vertical granular ventilation duct, characterized in that by limiting the rotation angle to rotate by the rotation and at the same time by the rapid recirculation by its own weight during the recirculation operation to block the exhaust gas flowing back through the granular ventilation duct rescue. The method of claim 1,
Vertically ventilated ventilation, characterized in that the sealing member (S) for increasing the airtightness is formed in the damper housing 10 when the air passage is closed through the light damper plate (LD) and heavy damper plate (FD) Damper structure on the exhaust pipe connected to the duct. The method of claim 1,
The air passage of the damper housing 10 connected to the granular ventilation duct prevents the exhaust gas discharged through the granular ventilation duct from entering the air passage of the damper housing 10 once outward. And a wing piece (SP) for guiding the gas discharged through the air passage of the housing (10) to piggyback the flow of the exhaust gas.

Images