KR200432485Y1 - An excessive pressre control device for wind quantity inside the smoke control area of building - Google Patents

Abstract

The present invention relates to an air volume overpressure control device of a blowing line that maintains the differential pressure in the ventilation zone and blows air into the ventilation zone so as to block the inflow of smoke in the event of a fire in the building, and more specifically, to each ventilation zone A blowing line 12 having an upper portion open and a lower portion closed so as to supply a; A blower 14 installed at one side of the blower line to supply air, and a dam wave 11 installed to open and close the supplied air quantity according to the blower line set air pressure, which is installed at the discharge port 15 side of the blower; ; A wind volume overpressure control device having a wind pressure sensor 16 for detecting a pressure in the blowing line 12 and electrically connected to the dam 11 and the controller 17 to control the opening and closing of the dam 11. 10) It can maintain the wind pressure in the blowing line uniformly, and maintain the same wind pressure as the differential pressure in the ventilation area, and improve the efficiency of the differential pressure in the ventilation area. The present invention relates to an airflow overpressure control device of a building ventilation area, which reduces installation time due to maintenance and facilitates management according to the interlocking relationship of facilities.

Air flow overpressure controller, blower line, blower, wind pressure, ventilation area, differential pressure

Description

{An excessive pressre control device for wind quantity inside the smoke control area of building}

1 is a block diagram showing a conventional blowing line overpressure automatic discharge device.

Figure 2 is a schematic view showing another conventional blowing line overpressure control device.

Figure 3 is a schematic view showing a blower line airflow overpressure control device of the ventilation area of the present invention.

Figure 4 is an enlarged view of some extraction for the airflow high pressure control device of the present invention.

<Code Description of Main Parts of Drawing>

10: Air flow overpressure control device 11: Dampa

12: Blowing line 13: Smoke area

14: blower 15: discharge outlet

16: wind pressure sensor 17: control unit

18: connector

20: Automatic differential pressure control damper 21: Differential pressure sensor

The present invention relates to an airflow overpressure control device of the blowing line for maintaining the differential pressure in the ventilation zone and blowing air to the ventilation zone to block the inflow of smoke in the event of fire in the building. More specifically, in order to form a constant differential pressure in the ventilation zones formed in each floor, when the air flow generated from the blower is supplied to the blower line, the air pressure rises above the set wind pressure. When the airflow falls below, it is possible to maintain the differential pressure in the ventilation area by supplying the air volume of the blower, and to install the blower and the overpressure regulating dam at the same position so that the air volume overpressure control device of the building ventilation area can be easily managed. will be.

In general, the automatic ventilation system installed in the building is driven by a blower installed on the roof of the building in case of fire, and blows the air to the blowing line so that the air supplied to the blowing line is supplied by the automatic differential pressure control damper in the ventilation zone. The differential pressure is generated by raising the pressure so that outside smoke does not flow into the smoke control area in case of fire.

However, in the event of a fire, a blower installed on the roof is driven by the fire detector's signal to supply air to the blower line, but the blower line is a vertical line and the air passage of the automatic differential pressure control damper installed in the ventilation zone is a blower line. Since it is distributed at right angles from, the air pressure in the blower line must rise above a certain air pressure to supply air to the ventilation area.

Therefore, the blower installed on the roof blows air to the blower line, and the blower line continues to rise as the air fills up from the bottom, resulting in congestion as the length of the blower line increases, and congestion occurs in certain areas of the blower line. There is a problem that the pressure difference is not formed in the ventilation area is not well formed, and the blowing line continues to increase the wind pressure.

In addition, when the air pressure rises above the set air pressure in the ventilation zone, a swing-type door that opens and closes the ventilation zone is installed to open to the ventilation zone, which requires great power to open the door, so children and the elderly cannot open the door. There was a problem of not evacuating quickly through the district.

In order to solve such a problem in the related art, the applicant of the patent 419390, FIG. 1, has invented an automatic ventilation system 400 for a ventilation area of a building, and its configuration is such that smoke is introduced into the combustion area 130 during a fire. To prevent the pressure difference between the smoke control area 130 and the non-smoke control area does not rise above a certain value so that children and the elderly can easily open the door 300 of the smoke control area to enter and exit the smoke control area. To be evacuated quickly and safely to the air blowing line 120 connected to each of the ventilation zones, and installed at a predetermined position of the blowing line 120 to supply air into the ventilation zones to provide air pressure in the ventilation zones Blower 140 for increasing the height, and respectively mounted on a plurality of ends of the blower line 120 connected in communication with the respective ventilation area In the conventional automatic dehumidification system consisting of a vehicle pressure control damper (200) for regulating the differential pressure generated between the ventilation zone and the outside of the ventilation zone, the system is connected to a predetermined position of the blowing line in communication with the blowing line Bypass pipe 110 for bypassing the air flowing into the outside; It has a self-sensing sensor 160 for detecting the pressure in the blower line 120, is electrically connected to the control means is mounted to the bypass pipe 110, interlocked with the differential pressure control damper 200 or When the pressure in the blowing line is more than a predetermined value, the overpressure automatic discharge device 100 for opening the bypass pipe 110 to bypass the blowing air in the blowing line to the outside has been disclosed.

Figure 2 is another design of the original application of the air blowing line 120 connected to each of the ventilation area 130, and installed in a predetermined position of the blowing line to supply air into the ventilation area air pressure in the ventilation area Blower 140 for increasing the pressure, and the differential pressure control damper 200 is mounted to each end of the blowing line connected to each of the ventilation zones to control the differential pressure generated between the ventilation zone and the outside of the ventilation zones. In the normal automatic dehumidification system 400 made,

A blower 140 positioned at one side in communication with the blowing line 120 to blow air; An automatic differential pressure control damper 200 capable of opening and closing an end of the blowing line so as to control the differential pressure by supplying air of the blowing line to the ventilation area; A bypass pipe (110) connected to the blowing line to bypass the overpressured air flowing into the blowing line to the outside; When the air flow pressure in the blowing line is overpressure above the set value, the bypass pipe 110 is automatically opened, and when the pressure drops, the overpressure automatic discharge device 100 ′ is closed.

However, all of the above prior arts have a problem in that a bypass pipe 110 through which air is discharged after forming a duct of a blowing line to one side of the basement is discharged.

That is, the blower line 120 of the apartment supplies air from the upper part to supply the air to the automobile pressure control damper 200, and when the overpressure occurs, it is discharged to the outside through the bypass pipe 110 at the bottom of the blower line. When designing, there are inconveniences of securing a separate discharge passage and a complicated problem in construction. In particular, when overpressure is generated in the blower line 120, the air is blown to the blower by configuring the air to be discharged to the outside through the bypass pipe 110. The air is continuously supplied and the air of the blowing line is continuously discharged through the bypass pipe 110 by the overpressure automatic discharge device 100, 100 ′, thereby causing a malfunction of the self-sensing sensor 160 and being discharged more than the amount supplied. There was a problem that the air pressure does not drop because the amount of air is small.

The present invention is to solve such a problem, by installing a blower on the upper side of the blower line and an air volume overpressure control device in front of the discharge port of the blower to generate a constant differential pressure in the ventilation zone formed by each floor generated in the blower When supplying the air flow rate to the blower line, if the overpressure occurs and the overpressure occurs, cut off the air supply of the blower, and if the air pressure falls below the set blower pressure line, supply the airflow of the blower to maintain the differential pressure in the ventilation area, Another purpose is to install the blower and the overpressure control dama at the same position so that they can be easily managed, and the lower part of the blower line is closed so that the wind pressure flowed into the blower line is maintained uniformly with the differential pressure of the ventilation area without loss. To provide airflow overpressure control device in building ventilation area The.

Hereinafter, the present invention will be described in detail.

A blower 14 installed at one side of the blowing line 12 to blow air into the blowing line to maintain wind pressure and to supply air into the ventilation area 13 to increase air pressure in the ventilation area 13; An automatic differential pressure control damper (20) for supplying air in the blowing line to control the differential pressure in the ventilation area (13); In the overpressure automatic discharge device to automatically open the bypass pipe when the pressure in the blowing line 12 is formed over the set value, and close the bypass pipe again when the pressure drops,

A blowing line 12 whose upper part is open and the lower part is closed so as to supply air to each of the ventilation areas;

A blower 14 installed at one side of the blower line to supply air, and a dam wave 11 installed to open and close the supplied air quantity according to the blower line set air pressure, which is installed at the discharge port 15 side of the blower; ;

A wind volume overpressure control device having a wind pressure sensor 16 for detecting a pressure in the blowing line 12 and electrically connected to the dam 11 and the controller 17 to control the opening and closing of the dam 11. 10).

The blowing line is connected to each of the ventilation zone 13 and the connection pipe 18, the end of the connection pipe is automatically connected to the differential pressure sensor 21 in the ventilation zone 13, the differential pressure control damper to control the differential pressure It is a configuration connected with (20).

30 is the door or emergency stairs door and 31 is the handle.

  When described in detail based on the accompanying drawings, the actual example of the present invention configured as follows.

Figure 3 is an overall configuration diagram showing the blower line airflow overpressure control device of the ventilation area of the present invention, Figure 4 shows an enlarged portion of the extraction of the airflow high pressure control device of the present invention.

As shown in FIG. 3, the blower line in the present chamber is open at the top and connected to the blower 14 installed at one side thereof, and the lower part thereof is closed. The structure of the blowing line 12 formed as described above is suitable for the design of high-rise buildings, such as apartments, buildings.

In other words, apartments, buildings, hotels, etc., install a blower line vertically on one side of the building and smoke control zones 13 on each floor to reduce casualties, evacuate people and delay the spread of fire. By supplying the wind from the blower line 12 to the ventilation area 13 to maintain the differential pressure.

However, in order to install the automatic ventilation system as described above, a blower line 12 is essential, and the blower 14 is installed in the blower line 12 to supply air.

Therefore, in the event of a fire, the blower 14 is driven to blow air into the blower line 12 to supply air to the ventilation area 13 to maintain differential pressure. The wind supplied to the zone is blocked by the automatic differential pressure control damper 20 to prevent the air from being supplied anymore, but the blower 14 which supplies the air to the blower line 12 continues to operate to blow air. In (12), overpressure occurs.

Since the overpressure of the blower line 12 is a deterrent to maintaining the differential pressure in the ventilation area 13, the wind pressure of the blower line 12 should always be maintained uniformly with the differential pressure of the ventilation area 13.

In the air flow overpressure control device 10 according to the present invention, the blower 14 installed at one side of the blower line 12 is operated by a signal of a fire detector when a fire occurs to blow external air through the blower line 12.

The air blown into the blowing line is introduced into the ventilation area through the vehicle pressure control damper 20 installed in each ventilation area and maintains a predetermined differential pressure by a differential pressure sensor installed in the ventilation area.

When a predetermined differential pressure is formed in the ventilation area, the automatic differential pressure control damper 20 is closed to block the air of the blowing line from entering any more.

Even when the air inflow of the ventilation zone 13 is blocked by the automatic differential pressure control damper 20, the blower continues to operate so that a predetermined pressure is formed in the wind pressure of the blower line 12.

Since the blower continues to operate even though a predetermined wind pressure is maintained by blowing wind in the blower line 12 as described above, when the wind pressure sensor 16 installed in the blower line 12 rises above the predetermined air pressure of the blower line 12. This is detected and a signal is sent to the control unit 17, the control unit 17 again closes the wind wave 11 installed in the air volume overpressure control device 10 installed in the front of the blower 14 discharge port 15, the wind of the blower is no longer Do not enter.

In other words, when the overpressure is generated in the blower line 12, the present invention does not discharge air to a separate bypass pipe as in the prior art, but instead of discharging air from the blower 14, the air volume of the air pressure overpressure control device 10 is broken. In order to block the inflow of air to maintain the wind pressure of the blowing line (12).

 By maintaining the wind pressure in such a way to block the flow of air by blocking the blowing line 12 as described above, the balance with the differential pressure of the ventilation zone can be maintained to increase the efficiency of the differential pressure of the ventilation zone as well as the Malfunction can be prevented.

In addition, the blower line 12 of the present invention is closed to the lower end is not only efficient to maintain the differential pressure of the smoke control area 13 by blocking the flow of air, but also easy to install because there is no need to install a bypass pipe during construction And reduce the cost incurred in constructing automatic ventilation system.

In addition, the blower 14 is installed on the upper side of the blower line 12 of the present invention, and the air volume overpressure control device 10 and the damper 11 are installed on the front of the blower, thereby simplifying maintenance.

That is, when the overpressure automatic discharge device and the bypass pipe are installed at the lower part of the blower line, the manager should check the overpressure automatic discharge device installed in the basement or the lower floor and check the blower again to the rooftop. ) And the airflow overpressure control device 10 are installed in the same position, the manager can not only perform the inspection at the same time, but also have the advantage of shortening the inspection time by simply grasping and repairing and checking the electrical connection relations with each other. .

In addition, the automatic ventilation system equipped with the air volume overpressure control device 10 is equipped with the present invention is the blower 14 is driven in the event of a fire blows the external air through the blower line 12, from the blower line to each smoke zone The differential pressure control damper 20 connected to the dispensing pipe 18 is connected to the outside air where the air is blown into the ventilation zone 13 so that the air pressure in the ventilation zone 13 rises higher than that of the non-smoke control zone. Generates.

In addition, when the differential pressure of the ventilation zone 13 is less than the predetermined value, the automatic differential pressure control damper 20 is opened and blown air is introduced into the ventilation zone 13, when the predetermined differential pressure is increased, the air blown to close the ventilation zone ( 13) to prevent the differential pressure to rise by preventing the flow into.

According to the present invention, the pressure difference between all the ventilation zones 13 and the blowing line is raised to a predetermined value by the above operation, so that all automatic differential pressure control dampers 20 are closed to block the ends of each blowing line 12, even though the blowing line is closed. In addition to the overpressure, the blower 13 is continuously operated to increase the pressure in the blower line 12.

Blowing air flows into the ventilation area 13 through the closed opening / closing member of the automatic differential pressure control damper 20, so that the pressure difference between the ventilation area 20 and the blowing line rises and exceeds a predetermined set pressure.

When the differential pressure reaches the set value, the automatic differential pressure control damper 20 transmits a detection signal to the control unit 17, and the control unit 17 receiving the detection signal transmits a detection signal to the airflow overpressure control device 10. The control signal is transmitted to close the dam 11.

Since the air blown by the blower 14 is not introduced, the air pressure in the blower line 12 is maintained, so that the pressure difference between the ventilation area 13 and the non-smoke control area is maintained at a predetermined set value.

If the differential pressure of the smoke control zone is maintained as described above, the outside air does not flow into the smoke control zone in case of fire, thereby preventing the spread of fire and in case of fire, the elderly and children easily open the door 30 of the smoke control zone 13 and open the smoke control zone. Through (13) you can evacuate to a safe place quickly and safely.

Normally, the differential pressure set in the ventilation area is set to 40 pascals to block the smoke flowing into the ventilation area from the outside in case of fire so that people living in each household can be evacuated.

The differential pressure set in the above-mentioned ventilation zone is set to open and close the entrance door which blocks the inflow of smoke from the outside and opens into the ventilation zone. The differential pressure is set according to the structure of the building and the size and the necessity of the ventilation zone. 40 pascals, 50 pascals, or the like.

In addition, when the sprinkler is installed in the ventilation area, the differential pressure is set to less than that.

Therefore, if the air pressure automatic control device 10 is equal to the air pressure of the air blowing line 12 and the differential pressure of the ventilation area 13, the dam 11 of the wind pressure automatic control device 10 is closed, and the pressure difference of the ventilation area 13 is greater than that of the air pressure control device 10. If the wind pressure of the blowing line 12 is low, the dam 11 of the wind pressure automatic control device 10 is opened to maintain the wind pressure by blowing air to the blowing line (12).

In this way, the present invention prevents the pressure difference of the ventilation line 12 from the pressure difference of the ventilation zone 13 so that the pressure difference does not occur above the set pressure in the ventilation zone so that children and the elderly can easily open and close the door to the ventilation zone. I would have to.

In particular, the air volume automatic control device 10 of the present invention is characterized in that it is possible to block or supply the air of the blower according to the set wind pressure of the blowing line 12 by the wind pressure sensor 16.

 The automatic ventilation system of the present invention described above does not install a separate non-smoke control sensor to maintain the differential pressure in the ventilation zone, and the differential pressure of the ventilation zone is only controlled by the wind pressure detection sensor of the blowing line and the differential pressure sensor of the ventilation zone. It can be maintained.

The present invention has a blower installed on the upper side of the blower line, and an airflow automatic control device is installed in front of the discharge port of the blower, and closes the damper when the wind pressure of the blower line is higher than the set value. By installing the wind to blow, first, it is possible to maintain the wind pressure in the blowing line uniformly and at the same time to maintain the same wind pressure as the differential pressure of the ventilation zone, and to increase the differential pressure efficiency of the ventilation zone,

Second, by installing a blower and air volume automatic control device in Doyle, it reduces the travel time due to maintenance and makes it easy to manage according to the interlocking relationship of facilities.

Third, the upper part of the blower line is opened to be connected to the blower, and the lower part is closed to prevent the loss of the set wind pressure in the blower line and reduce the cost of installing the automatic ventilation system.

Claims (2)

A blower 14 installed at one side of the blowing line 12 to blow air into the blowing line to maintain wind pressure and to supply air into the ventilation area 13 to increase air pressure in the ventilation area 13; An automatic differential pressure control damper (20) for supplying air in the blowing line to control the differential pressure in the ventilation area (13); In the overpressure automatic discharge device to automatically open the bypass pipe when the pressure in the blowing line 12 is formed over the set value, and close the bypass pipe again when the pressure drops, A blower line 12 having an upper portion open and a lower portion closed to supply air to each of the ventilation zones; A blower 14 installed at one side of the blower line to supply air, and a dam wave 11 installed to open and close the supplied air quantity according to the blower line set air pressure, which is installed at the discharge port 15 side of the blower; ; Having a wind pressure sensor 16 for sensing the pressure in the air blowing line 12, and electrically connected to the dam 11 and the control unit 17 to control the air flow overpressure control device 10 to control the opening and closing of the dam 11 Airflow overpressure control device of the building ventilation area characterized in that the configuration. The method of claim 1, Blowing line is connected to each of the ventilation zone 13 and the connection pipe 18, the end of the connection pipe is provided with an automatic differential pressure control damper 20 is electrically connected to the differential pressure sensor 21 in the ventilation zone 13 and blown An airflow overpressure control device of a building ventilation area characterized by a configuration connected to the airflow overpressure control device so as to maintain the line pressure of the line and the differential pressure of the ventilation zone.

Images