KR20180059642A - Ventilation system with radon abatement function - Google Patents

Abstract

The present invention relates to a ventilation system with a radon abatement function. The ventilation system includes: a radon sensor (10) installed indoors; an air circulator (20) installed outdoors and having an air supply/exhaust pipes (21, 22) communicating with an indoor room; a filter (30) installed inside the air circulator (20) so as to correspond to an exhaust pipe (24); a radon inflow pipe (40) connected to the exhaust pipe (24) for introducing radon in the room; a damper (50) rotatably installed at a connection portion between the exhaust pipe (24) and the radon inflow pipe (40) to selectively block the flow path of the exhaust pipe (24) or the radon inflow pipe (40); and a controller (60) that receives signals from the radon sensor (10) and controls the operation of the damper (50). The present invention can improve the functionality and usability of the ventilation system having the radon abatement function.

Description

[0001] VENTILATION SYSTEM WITH RADON ABATEMENT FUNCTION [0002]

The present invention relates to a ventilation system having a radon abatement function, and more particularly, to a ventilation system having a radon abatement function capable of simply and efficiently reducing radon contained in indoor air.

Generally, Radon (Rn) is an element generated when the radium contained in natural materials such as soil or rock collapses, and is a colorless, tasteless, odorless radioactive gas in an inert gas form.

These radon concentrations are several tens to hundreds of times higher in indoor than indoor.

Particularly, since radon is a gas, it does not directly affect the body itself, but if it accumulates in the body through respiration, it becomes a main cause of lung cancer. As a result, research and development for reducing radon at home and abroad have been actively conducted.

As shown in FIG. 1, the conventional radon reduction ventilation system includes a radon sensor 1 for detecting the presence or absence of radon in a room; A ventilator 2 for discharging the radon detected by the radon sensor 1 to the outside of the room; A control unit (3) for controlling the driving of the ventilator (2); And a communication unit 4 for connecting the ventilation unit 2 and the control unit 3. [ The radon abatement system having such a structure is disclosed in Japanese Patent Application Laid-Open No. 10-2014-0106350, and a detailed description thereof will be omitted.

However, since the indoor air containing the radon is discharged to the outside through the ventilator (2) without additional filtration, the radon can be returned to the indoor space of the surrounding building, Can be one cause of contamination.

In addition, the structure for reducing the radon is relatively complicated, and there is no connection with the existing ventilation system.

This results in lowering the functionality and usability of the radon reduction ventilation system.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a radon reducing function capable of filtering out radon in conjunction with a ventilation system, Thereby providing a ventilation system.

According to an aspect of the present invention, there is provided a ventilation system having a radon reduction function, including: a radon sensor installed in a room; An air circulator installed outside the room, the air circulator having an inlet / outlet pipe communicating with the room; A filter installed inside the air circulator so as to correspond to the exhaust pipe; A radon inlet pipe connected to the exhaust pipe for introducing radon in the room; A damper rotatably installed at a connection portion of the exhaust pipe and the radon inflow pipe to selectively block the flow path of the exhaust pipe or the radon inflow pipe; And a controller for receiving signals from the radon sensor and controlling the operation of the damper.

The ventilation system having the radon reduction function according to the present invention can filter out the radon components contained in the indoor air through the filter and then discharge it to the outside to solve environmental problems such as air pollution.

As a result, the functionality and usability of a ventilation system having a radon reduction function can be improved.

In addition, it can actively link with the existing ventilation system to simplify the structure of the ventilation system having the radon reduction function, and to reduce the economic cost such as the parts cost and the installation cost.

1 is a block diagram of a conventional ventilation system having a radon reduction function,
FIG. 2 is a schematic view of a ventilation system having a radon reduction function according to the present invention. FIG.
FIG. 3 is a view showing the structure of an air circulator of a ventilation system having a radon reduction function according to the present invention. FIG.
FIG. 4 is an operational state diagram of a damper of a ventilation system having a radon reduction function according to the present invention,
Figure 5 is a partial enlarged view of a ventilation system having a radon reduction function according to the present invention;
6 is a perspective view showing a filter of a ventilation system having a radon reduction function according to the present invention,
Figs. 7A and 7B are cross-sectional views showing the coupling structure of Fig. 6,
FIG. 8 is a plan view showing an arrangement state of a radon collecting tube in a ventilation system having a radon abatement function according to the present invention,
FIG. 9 is a cross-sectional view of a trapping part of a radon collecting tube of a ventilation system having a radon abatement function according to the present invention,
10 is a block diagram of a ventilation system having a radon reduction function according to the present invention.

Hereinafter, a ventilation system having a radon reduction function according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 5, a ventilation system having a radon reduction function according to the present invention includes a radon sensor 10 installed in a room; An air circulator (20) installed outside the room, the air circulator (20) having an air supply pipe (21) and an exhaust pipe (22) communicating with the room; A filter 30 installed inside the air circulator 20; A radon inlet pipe 40 connected to the exhaust pipe 22; A damper 50 rotatably installed at a connection portion of the exhaust pipe 22 and the radon inflow pipe 40; A controller 60 (see Fig. 10) for controlling the operation of the damper 50; A radon blocking coating layer 70 formed on inner surfaces of the side walls W and the bottom B of the room, respectively; A radon collecting pipe 80 provided under the floor B of the room and connected to the radon inlet pipe 40; And an auxiliary filter (90a) and an auxiliary fan (90b) installed inside the radon collecting pipe (80).

The radon sensor 10 senses the concentration of radon present in the room in real time. The radon sensor 10 sends a signal to the controller 60 when the indoor radon concentration exceeds a reference value.

On the other hand, it is preferable that at least one radon sensor 10 is installed in a lower region of a room, but the installation position and the number of the radon sensor 10 can be appropriately adjusted as needed.

The air circulator 20 is for circulating (ventilating) the air in the room, and a pipe-like filter attaching / detaching opening 23 is formed in the inside of the air circulating device 20 so that the filter 30 is detachably coupled.

The air supply pipe (21) is for supplying outside air to the room, and the exhaust pipe (22) is for discharging indoor air to the outside.

On the other hand, the air circulator (20) has a casing (25) in which an internal space is defined by a plurality of partitions (24); A heat exchanger (26) installed between the plurality of partitions (24) for exchanging indoor air and outdoor air with each other; A cooler supply unit 27 installed inside the casing 25 for heating or cooling the outside air passing through the heat exchanger 26; an air supply fan 28 for supplying outside air to the room; And an exhaust fan 29 for exhausting the inside air to the outside.

The filter 30 functions to filter the radon contained in the indoor air. The filter 30 is detachably attached to the filter attachment / detachment opening 23 of the air circulator 20 corresponding to the exhaust pipe 22 do. This makes it possible to facilitate the replacement work as well as the installation of the filter 30. [

As shown in Figs. 6 to 7B, the filter 30 includes a case portion 32; A support portion 34 provided on the outer surface of the case portion 32; And a filter portion 36 provided inside the case portion 32.

The casing part 32 is formed in the same shape as the filter attachment / detachment opening 23 of the air circulator 20 and is inserted into the same, and synthetic resin is used as the material of the casing part 32. The case 32 has a structure in which the first case 32a and the second case 32b are separated so as to facilitate the replacement operation of the filter unit 36 and to partially replace the filter unit 36 And a thread 31a is formed at one end thereof.

A pair of mounting protrusions 31b for stably mounting the filter unit 36 are formed on the inner surface of the case 32 at regular intervals.

The support portion 34 is for firmly supporting the case portion 32 on the inner surface of the filter attachment / detachment opening 23 of the air circulator 20 and includes a fastening ring 34a and a plurality of elastic blades 34b.

A thread 35 is formed in the fastening ring 34a and is fastened to a thread 31a formed at one end of the case 32. [ The plurality of resilient blades 34b are made of a metal material bent in the shape of '∧' so as to have an elastic supporting force, and extend from the fastening ring 34a by a predetermined length and are positioned on the outer surface of the case 32. Of course, the shape of the elastic wings 34b can be suitably changed within a range capable of having an elastic supporting force, and the number and arrangement of the elastic wings 34b can also be changed.

When the case 32 is inserted into the filter attachment / detachment port 23 of the air circulator 20, the elastic blade 34b located on the outer surface of the case 32 is deformed and elastically supported on the inner surface of the filter attachment / The installation state of the case 32 can be more firmly and stably maintained.

A frictional portion 33 is formed on the outer surface of the elastic blade 34b to prevent the support 34 from slipping or the like. The frictional portion 33 is provided with a friction force including a rubber pad or a friction coating layer. Various kinds of things that can be applied can be applied.

The filter portion 36 is provided between the pair of mounting protrusions 31b formed in the case portion 32 and is provided in a plurality of rows. The first and second filters 36a, 36b, and 36c are classified into a first filter 36a, a second filter 36b, and a third filter 36c. The first and second filters 36a, 36b, Filter, and carbonized wood filter, respectively.

On the other hand, the HEPA filter, the diatomaceous earth filter, and the carbonized wood filter are well known in the art, and a detailed description thereof will be omitted.

The radon inlet pipe 40 is for introducing the indoor radon, and the air inlet 42 through which the indoor air is introduced is positioned adjacent to the floor B of the room to enhance the inflow efficiency of the radon.

The radon inlet pipe 40 is formed with a radon adsorption layer 44 capable of adsorbing radon on its inner surface and is contained in the room air passing through the radon inlet pipe 40 through the radon adsorption layer 44 Radon can be removed primarily. As the radon adsorption layer 44, a coating material mainly composed of charcoal or lacquer is used, and if necessary, a variety of known materials having a radon adsorption function can be used.

The damper 50 selectively blocks the flow path of the exhaust pipe 22 or the radon inflow pipe 40. When the room air is ventilated normally, as shown in FIG. 4A, The damper 50 is rotated by the controller 60 as shown in FIG. 4 (b) when exhausting is performed only through the exhaust pipe 22 by shutting off the flow path of the pipe 40, So that the exhaust gas is discharged only through the radon inflow pipe 40 by shutting off the flow path of the exhaust pipe 22.

Due to the constitutional characteristic of the damper 50, only indoor air containing radon can be separated and discharged to the outside, and also the capacity of the exhaust fan 29 of the air circulator 20 can be reduced.

It is needless to say that various types of dampers 50 may be selectively applied to the damper 50.

The controller 60 receives the signal from the radon sensor 10 when the radon sensor 10 and the damper 50 are connected by the communication unit as shown in FIG. The indoor air is discharged only through the radon inflow pipe 50 by blocking the flow path of the exhaust pipe 22. [ Of course, when the radon concentration is lower than the reference value, the damper 50 returns to its original position and blocks the flow path of the radon inlet pipe 50.

The radon barrier coating layer 70 is used to prevent radon present in the lower part of the floor B of the room from entering the room, and known radon blocking components such as diatomaceous earth, carbonized wood, charcoal, and lacquer are used.

The radon collection pipe 80 is for collecting the radon introduced from the bottom of the room.

As shown in FIGS. 8 and 9, the radon collecting pipe 80 includes a connecting portion 82 connected to the radon inlet pipe 40; And a plurality of collecting parts 84 which are branched from the connecting pipe 82 and are arranged side by side in a line and in which a plurality of air vents 83 are formed on the outer circumferential surface.

Particularly, the air vent 83 is for introducing radon and may be formed in all or a part of the collecting part 84.

The auxiliary filter 90a is for filtering the radon trapped in the radon collecting pipe 80 and has the same configuration as the filter 30 described above, and thus a detailed description thereof will be omitted.

The auxiliary exhaust fan 90b is for transferring the radon trapped in the radon collecting pipe 80 to the auxiliary filter 90a so that the auxiliary exhaust fan 90b is operated so that the radon is discharged when the radon is discharged through the radon inlet pipe 40 And the on / off operation thereof is automatically controlled by the controller (60).

The operation state of the ventilation system having the radon reduction function described above will be briefly described below.

First, the radon continuously generated in the soil or rock existing in the lower part of the floor B of the room is introduced into the radon collection tube 80 through the plurality of air vents 83 formed in the radon collection tube 80 And is collected.

Part of the radon that has not been collected through the radon collecting pipe 80 is blocked by the radon barrier coating layer 70, and the rest enters the room. The radon introduced into the room is detected by the radon sensor 10 and the controller 60 operates the damper 50 to open the flow path of the radon inflow pipe 40 when the concentration reaches a predetermined value or more, And the air is discharged to the outside through the exhaust pipe (22). At this time, the auxiliary exhaust fan 90b is also operated so that the radon trapped in the radon collecting pipe 80 is discharged together through the exhaust pipe 22.

And harmful substances such as radon exhausted through the exhaust pipe 22 are filtered while passing through the filter 30 inside the air circulator 20.

10: Radon sensor 20: Air circulator
21: a gas engine 22: an exhaust pipe
23: filter attachment / detachment port 30: filter
31a: thread 32: case part
34: support portion 34a: fastening ring
34b: elastic blade 36: filter part
40: Radon inlet pipe 50: Damper
60: Controller 70: Radon blocking coating layer
W: side wall B: bottom

Claims (6)

A radon sensor 10 installed indoors;
An air circulator (20) installed outside the room and having an air supply / exhaust pipe (21, 22) communicating with the room;
A filter (30) installed inside the air circulator (20) so as to correspond to the exhaust pipe (24);
A radon inlet pipe (40) connected to the exhaust pipe (24) for introducing radon in the room;
A damper 50 rotatably installed at a connection portion between the exhaust pipe 24 and the radon inlet pipe 40 to selectively block the flow path of the exhaust pipe 24 or the radon inlet pipe 40;
And a controller (60) for receiving signals from the radon sensor (10) and controlling the operation of the damper (50).
The method according to claim 1,
Wherein the filter (30) is detachably installed inside the air circulator (10).
The method of claim 2,
A filter attachment / detachment opening 23 is formed in the air circulator 10,
The filter (30) includes a casing (32) inserted into the air inlet (22); A support portion (34) provided on the outer surface of the case portion (32) and closely supported by the air intake port (22); And a filter unit (36) provided inside the case part (32).
The method of claim 3,
A thread 31a is formed at one end of the case 32,
The support 34 includes a fastening ring 34a fastened to the thread 31a; And a plurality of elastic blades (34b) extending from the fastening ring (34a) and positioned on the outer surface of the case part (32) and elastically supported by the air inlet (22) system.
The method of claim 4,
Characterized in that the plurality of resilient vanes (34b) have a curved shape. The ventilation system
The method according to claim 1,
And a radon blocking coating layer (70) formed on the side walls (W) and the bottom (B) of the room, respectively, for blocking inflow of the radon into the room.

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