KR101288820B1 - Smoke control damper system of building - Google Patents

Abstract

PURPOSE: A refining damper system of building is provide to prevent being wet through a guiderail which guides a screen part. CONSTITUTION: A refining damper system of building prevents smoke getting into an accessory room supplying the air with pressure into the accessory room which is which is a refining room connected to an outlet of air by a ventilator in case of fire through the outlet of air by installing the outlet of air on a vertical air duct in a building and a masonry wall between the vertical air duct and the accessory room. The refining damper system of building comprises a retarding motor (500), a controller, a shaft (550), a couple of serrated wheels (520,520-1), a bearing part, a screen part (800), a couple of pulleys (900,900-1), each balanced weight (600,600-1), and wire ropes (660,660-1).

Description

Smoke Control Damper System of Buildings

The present invention relates to a smoke control damper system installed in the air supply duct or discharge duct of a building such as an apartment, officetel. In general, the smoke control damper installed in the air supply duct or the exhaust duct operates a large blower installed outside in the event of a building fire to generate high-pressure, high-air volume air, and special evacuation staircases in each floor through vertical airways installed from the basement to the rooftop of the building. Alternatively, forced air is blown into the attached room (stairway room) to prevent fire smoke generated in the room of each floor from leaking into the accessory room, the ventilation area. On the other hand, if the air pressure of the ancillary room as described above is too large, the occupant will not be able to evacuate to the annex room such as a staircase in the event of fire. Therefore, evacuation stairs or ancillary room must prevent fire smoke from leaking inside each floor in case of fire, and maintain proper plus air pressure so that occupants in the room can push and evacuate doors or fire doors. The air pressure in the ancillary room is usually defined as plus 40 to 60 Pa. In addition, the above-described dehumidification damper system is installed separately for each floor, the blade for opening or closing the high-pressure high-air flow path in the duct, the motor for operating the blade, the indoor pressure sensor for measuring the indoor pressure, It is composed of a controller for controlling the operation of the deceleration motor by receiving the output value of the accessory chamber internal pressure sensor, the indoor pressure sensor and the accessory chamber internal pressure sensor. The damping damper system configured as described above is effective to allow the blades to completely open or completely close the flow path of the air supply duct at the same time, and in general, the air supply duct crosses the blades in normal times and closes the flow path in case of fire. By opening the blade of the air supply duct so that the outside air flows into the room, the air pressure of the evacuation staircase or the accessory room is positive to prevent the spread of fire smoke to the entire floor.

The prior art related to the present invention is disclosed in Korean Patent Application No. 10-2011-0116029 filed by the applicant.

1 is a block diagram of a smoke suppression system of a conventional high-rise building. In FIG. 1, the smoke suppression system of a conventional high-rise building includes a vertical duct 400 configured inside the vertical passage of an apartment or an officetel building and an air supply 170 for each floor on one side of the vertical duct 400. Supplying fresh air through the mechanism 170 and the vertical duct 400, or in the event of a fire to pressurized air to the ventilation area connected to each air supply unit 170 by a blower to prevent smoke from leaking out of the ventilation area. will be. The present invention is to open and close the air supply 170 temporarily in a high-rise building equipped with a vertical duct 400 and the air supply 170 provided for each floor configured as described above to one side space of the vertical duct in the vertical passage It is installed in the deceleration motor 100 for conveying the screen portion 200 made of steel plate or the like up and down, and to transfer the power of the reduction motor 100 to the upper driven rotating part 150 to the motor shaft A rotating rod 115 that interlocks, a first chain gear 110 and a second chain gear 120 configured to be spaced apart from the rotating rod 115 by a predetermined distance, and a first supporting the rotating rod 115 at both ends. The first rope chain 160 and the circle shape of a circle shape rotating in engagement with the bearing portion 130 and the second bearing portion 140, respectively, the first chain gear 110 and the second chain gear 120. Second rope chain 160-1, one side of the first rope chain 160, and the second Screen portion 200 which is configured to be horizontally at intervals between one side of the rope chain (160-1) to which a plurality of opening and closing portion 180 made of steel plates and the like to open and close the air supply 170 of each layer and The lower first chain gear 210 and the lower second chain for supporting and rotating the other ends of the first rope chain 160 and the second rope chain 160-1 at the lowest floor of the vertical passage of the high-rise building. A lower driven rotary part 250 composed of a gear 220, a lower rotating rod 215 engaged with the lower first chain gear 210 and a lower second chain gear 220, and rotating the lower rotating rod 215. The lower first bearing part 230 and the lower second bearing part 240 which are configured on both sides of the lower rotating rod to support it. In order to open and close the air supply 170 of each layer in the above includes an opening and closing portion 180 consisting of a plurality of iron plate or the like fastened between one side of the first rope chain 160 and the second rope chain (160-1). If the vertical movement distance of the screen unit 200 is longer than the longitudinal length of the air supply unit 170, the air supply unit can be opened and closed sufficiently, and each opening / closing unit 180 of the air supply unit 170 can be opened and closed completely. It is preferable to configure larger than the size, and also the upper limit switch 310 at the maximum rising point or the maximum falling point of the screen portion 200 in order to limit the vertical movement range of the screen portion 200 to a sufficient degree to fully open and close the air supply. ) And the lower limit switch 320 on both sides of the vertical duct is preferably limited to the vertical movement range of the screen unit 200. In addition, in order to physically limit the vertical movement range as described above, it is preferable that the stopper 330 is further included and installed to prevent the screen from moving upward and downward a predetermined distance. Also, the first rope chain 160 and the second rope chain 160-1 may include the first chain gear 110, the second chain gear 120, the lower first chain gear 210, and the lower second chain. A certain portion that rotates in engagement with the chain gear 220 is configured in the form of a chain so that the rope chain can rotate, but the other part of the opening and closing portion 180 is fastened in the form of a straight rod or plate rather than a rope chain. It is preferable that the screen unit 200 is fastened to a plurality of opening and closing portion 180 made of an iron plate or the like at intervals in consideration of the interlayer height. The dehumidification damper system of the high-rise building of the present invention configured as described above is a reduction motor to move the screen portion 200 including a plurality of opening and closing portion 180 configured on one side of the rope chain (160, 160-1) up and down a certain range. When driving the 100, the rope chain (160, 160-1) by the drive of the reduction motor is rotated, it is characterized in that can open and close the air supply 170 configured in each floor of the building at a time. In addition, the rope chain portion on which one side of the rope chain, that is, the screen portion 200 is formed, indicates that both ends of the screen portion are guided up and down within the sliding groove 205. As described above, the screen portion 200 slides. By moving in the groove 205 it is possible to guide the transfer of the screen portion in a sense of stability when moving up and down. In the above, the number of floors has been exemplified, but it is also applicable to one floor only by the configuration of the screen part composed of one opening and closing part.

The smoke damper of a conventional high-rise building as described above has a problem that a lot of leakage occurs through the guide rail, and that a heavy load is applied to the motor during vertical movement of the screen unit. In addition, there is a problem that the wire rope is relaxed or stretched over time or the temperature change, the position of the screen portion and the air supply inconsistent or the vertical movement of the wire rope is incomplete.

The smoke control damper system of a building of the present invention for solving the problems of the prior art as described above is a controller for controlling the deceleration motor and the blower by combining a fire detector, an internal chamber pressure sensor, an indoor pressure sensor, a limit detection sensor switch signal, and the like; A deceleration motor reversed by a controller, a pair of cog wheels fastened to rotate on a shaft connected to the shaft of rotation of the motor, a chain fastened to each of the pair of cog wheels and rotated, and fastened to the other end of each chain A screen part, respective wire ropes fastened to both lower ends of the screen part, respective pulleys for assisting rotation of the respective wire ropes, and a tension adjusting part for temperature correction fastened to the wire ropes wound and passing through the pulleys; Balanced weights are fastened to the upper or lower portion of the tension control unit, and the other of the balance weights It is to form a chain and the wire rope is a circle as a whole that which the fastening chain. As described above, the chain and the wire rope forming one circle are each chain and wire rope engaged with the upper pair of gear wheels when the reduction motor is driven, and the screen connected to the pair of chains is rotated as described above. The additional air supply can be opened and closed efficiently.

The damping damper system of the present invention building configured as described above is effective to prevent leakage through the guide rail for guiding the screen portion. In addition, when the screen unit is moved up and down, the balance is added to the effect that can be moved up and down the screen unit with a small motor power. In addition, the tension of the wire rope in accordance with the change of temperature in the summer or winter can be corrected by the tension control unit to effectively move up and down the screen.

1 is a block diagram of a smoke control damper system of a conventional high-rise building,
Figure 2 is a perspective view of a state in which the air supply damper system of the building damper damper system of the first embodiment of the present invention closed;
3 is a perspective view of an air-conditioning damper system of a building according to the first embodiment of the present invention with the air supply opening open;
4 is a side view of a state in which the air supply damper system of the building according to the first embodiment of the present invention is closed;
Figure 5 is a side view of a state in which the air supply opening of the smoke control damper system of the building according to the first embodiment of the present invention,
Figure 6 is a perspective view of a state in which the air supply damper system of the building damper damper system of the second embodiment of the present invention,
7 is a perspective view of a state in which the air supply vent is opened by the smoke suppression system of a building according to the second embodiment of the present invention;
8 is a cross-sectional view of the side guide rail applied to the present invention,
9 is a detailed configuration diagram of the tension control unit applied to the present invention,
10 is a block diagram of a controller applied to the present invention.

Referring to Figures 2 to 10 with respect to the smoke control damper system of the present invention building having the above object as follows.

Figure 2 is a perspective view of a state in which the exhaust control damper system of the building according to the first embodiment of the present invention closed the air supply. 2 is a dehumidification damper system of the building according to the first embodiment of the present invention is a reduction motor 500 is installed on the upper part of the vertical wind (50), a shaft 550 connected to the rotation shaft of the reduction motor 500, A pair of bearing parts 510 and 510-1 supporting the shaft to rotate, a pair of gears 520 and 520-1 installed on the rotating shaft 550 to rotate inside the pair of bearing parts, and A pair of chains 650 and 650-1 connected to the pair of gear wheels 520 and 520-1 to rotate, a screen portion 800 having a square shape fastened to one side of the pair of chains, and It is fastened to both ends of the lower end of the screen portion 800, the wire rope (660, 660-1) is fixed to the lower pair and the pair of pulleys (900, 900-1) for assisting the vertical transfer of the screen portion and a pair for correcting the relaxation of the wire rope Tension control unit (700, 700-1) of the screen and to facilitate the vertical transfer of the screen Is connected to each of the chains 650 and 650-1 through the respective balancing weights 600 and 600-1 to form a circle. The ventilation control damper system of the building configured as described above indicates that the air supply port 1000 formed on the masonry wall of the building can be opened and closed by the screen unit 800 by the driving of the reduction motor 500. 2 illustrates a state in which the screen part 800 is closed by the driving of the reduction motor 500. For example, the embodiment is implemented by a pair of bearing parts, but by one bearing part 510-1, the shaft may be configured to be easily rotated.

3 is a perspective view of a state in which a ventilation damper system of a building according to the first embodiment of the present invention is opened with an air supply. In FIG. 3, the smoke control damper system of the building according to the first embodiment of the present invention drives the reduction motor 500 to move the screen portion 800 upward so that the screen portion 800 opens the air supply port 1000. Will be. When driving the screen unit 800 by the driving of the motor as described above by a small motor power by the balance weight (600, 600-1) fastened to the respective chain (650, 650-1) inside the vertical wind (50) The screen portion 800 can be easily transported up and down. In order to maintain the weight of the balance weights 600 and 600-1 with the screen portion, the movement of the screen portion can be made with less power. In addition, in order to compensate for relaxation of the wire ropes 660 and 660-1 due to temperature changes such as summer or winter time, when the tension control units 700 and 700-1 are fastened to the wire ropes 660 and 660-1, It can prevent the malfunction due to the loosening of the rope. In addition, FIG. 3 illustrates that the air supply unit 1000 opens the screen unit 800 and transfers the high-pressure high air volume air from the separately installed blower (not shown) to the attached room or the evacuation stairway through the vertical wind speed 50. In addition, maintaining the air pressure of the evacuation stairs room to the positive air pressure indicates that the fire smoke generated in the room can be prevented from leaking into the attached room or the evacuation stairs room.

4 is a side view of a state in which the air supply damper system of the building according to the first embodiment of the present invention is closed. In FIG. 4, the smoke control damper system of the building according to the first embodiment of the present invention includes an air supply device 1000 formed in a masonry wall 1100 formed between a vertical wind velocity 50 and an auxiliary room or an evacuation stairway room in each floor, and the air supply device. Screen portion 800 for opening and closing, gear wheels 520 and 520-1 fastened to the shaft 550 of the motor for transferring the screen portion 800 up and down, and the gear wheels 520 and 520-. Chains 650 and 650-1 which are engaged with each other by the rotation of 1) and rotated in engagement with the gears 520 and 520-1 which are fastened to one end of the screen part 800. Balance weights 600 and 600-1 fastened to the other end of -1), and a tension adjusting part fastened to the lower portions of the balance weights 600 and 600-1 and correcting stretching and relaxation of the wire ropes 660 and 660-1. (700, 700-1), the wire rope (660, 660-1) fastened to the tension control unit (700, 700-1), and the lower masonry wall (1100) is installed near the Pulleys 900 and 900-1 assisting the rotation of the ropes 660 and 660-1, and wire ropes 660 and 660-1 passing through the pulleys 900 and 900-1 are provided in the lower guide rail 830. Passing through the structure is fastened to the lower end of the screen portion 800. The first embodiment of the present invention configured as described above, the smoke control damper system is driven by the reduction motor 500, the gear wheels (520, 520-1) is rotated in the clockwise or counterclockwise direction the screen portion 800 suddenly The mechanism 1000 is opened. As described above, the opening and closing of the screen unit 800 by the driving of the reduction motor 500 is because the balance weights 600 and 600-1 fastened to the ends of the chain are similar in weight to the screen unit 800, and thus have little power. In addition, the screen portion 800 is a structure that can be moved up and down. In addition, the tension adjusting unit (700, 700-1) configured in the lower portion of the balance weight is the chain (650, 650-1) and the wire rope (660, 660-1) for stretching and relaxation of the wire rope (660, 660-1) It is possible to keep the overall tension of the circle consisting of) constant. In addition, in the upper guide rail 810 in FIG. 4, a screen hole 800 is formed to enter and exit, and the long hole has a structure in which the shape maintaining film iron film 840 is formed at both sides to prevent leakage of smoke. The lower guide rail 830 has a structure in which a shape maintaining film iron film 840-1 is formed, and respective limit switches 850 and 850-1 are installed at the lower end of the upper masonry wall 1100 and the upper end of the lower masonry wall. It is to act to detect the opening and closing of the screen unit 800. In the above example, the air supply opening and closing of the screen 800 is sensed as a limit switch, but a contactless sensor switch is also possible, and the limit switch or contactless sensor installed at the upper and lower portions of the air supply device 1000 in the above. When the two input signals of the switch are received, the screen unit 800 determines that the air supply unit 1000 is closed. If the two input signals are not received, the screen unit 800 determines that the air supply unit 1000 is opened. You can do it.

5 is a side view of a state in which the air supply vent is opened by the smoke control damper system of a building according to the first embodiment of the present invention. In FIG. 5, the smoke control damper system of the building according to the first embodiment of the present invention drives the gear wheels 520 and 520-1 by driving the reduction motor 500 when it is necessary to increase the air pressure of the accessory chamber in the state of FIG. 4. When rotated in a clockwise direction, the chains 650 and 650-1 that rotate in engagement with the cog wheels 520 and 520-1 rotate, and the screen portion 800 passes through the long hole formed in the upper guide rail 810 and upwards. Is transferred to. As described above, the balance weights 600 and 600-1 are fastened to the chain located on the right side of the gears 520 and 520-1 in order to easily transport the screen unit 800. When the screen unit 800 is moved upward as described above, since the signal input of the upper limit switch 850 and the lower limit switch 850-1 is not received, the driving of the motor is stopped to complete the opening of the air supply. will be. In addition, when it is necessary to close the air supply port 1000, if the gear wheels 520 and 520-1 are rotated counterclockwise by rotating the driving of the reduction motor 500 in the reverse direction, the screen unit 800 is When moving downward and the contact signal of the upper limit switch 850 and the lower limit switch 850-1 is received, the screen unit 800 determines that the closing of the air supply port is completed and stops driving of the motor. It is.

6 is a perspective view of a state in which the air supply damper system of the building according to the second embodiment of the present invention is closed. In FIG. 6, the second embodiment of the present invention provides a damping damper system including a reduction motor 500 installed on an upper portion of the vertical wind turbine 50, a shaft 550 connected to a rotation shaft of the reduction motor 500, and A pair of bearing parts 510 and 510-1 for supporting the shaft to rotate, a pair of gears 520 and 520-1 installed and rotated on the rotation shaft 550 inside the pair of bearing parts, and A pair of chains 650 and 650-1 connected to the pair of gear wheels 520 and 520-1 to rotate, a screen portion 800 of a square shape fastened to one side of the pair of chains, and the screen The wire rope 660-2 fastened to the center of the lower end of the part 800 is fixedly installed at the bottom thereof, and has a stick shape that balances the weight of the pulley 900 and the screen part 800 to assist the vertical movement of the screen part. It is fastened to the center of the balance bar 600-2 and the balance bar 600-2, the balance bar 600- 2) wire ropes 660 and 660-1 are fastened to both ends of the wire ropes respectively, and a pair of tension adjusting units 700 and 700-1 and the respective wire ropes are respectively fixed to the wire ropes. It is shown that it is connected to the respective chains (650, 650-1) at the top of the tension adjustment unit. The ventilation control damper system of the building configured as described above indicates that the air supply port 1000 formed on the masonry wall of the building can be opened and closed by the screen unit 800 by the driving of the reduction motor 500. In addition, FIG. 6 illustrates a state in which the screen part 800 is closed by the driving of the reduction motor 500.

7 is a perspective view of a state in which an air supply opening is opened by a smoke suppression system of a building according to a second embodiment of the present invention. In FIG. 7, in the building damping damper system according to the second embodiment of the present invention, when the screen unit 800 is moved upward by driving the reduction motor 500, the screen unit 800 opens the air supply port 1000. will be. As described above, when driving the screen portion 800 in which one side is fastened to each of the chains 650 and 650-1 by driving the motor, the other side of each of the chains 650 and 650-1 inside the vertical wind velocity 50. Balanced to the ends of the tension adjustment unit 700, 700-1 and the respective wire ropes 660 and 660-1 connected to the respective tension control units and the ends of the respective wire ropes 660 and 660-1. The wire rope 660-2 and the wire rope 660-2 that one side is fastened to the center of the bar 600-2 and the balance bar 600-2 and the other side is fastened to the center of the screen bar 800. ) By the pulley 900 to rotate to be able to easily transport the screen portion 800 up and down with a small motor power. The second embodiment as described above is to balance the weight of the balance bar 600-2 with the screen portion while using a single pulley 900 can move the screen portion 800 with less power. . In addition, in order to compensate for relaxation of the wire ropes 660, 660-1, and 660-2 due to temperature changes such as summer or winter, the tension adjusting units 700 and 700-1 may be connected to the wire ropes 660 and 660-1. It is to be fastened respectively, the tension control unit (700, 700-1) is to prevent the malfunction due to the relaxation of the wire rope. In addition, FIG. 7 shows that the air supply unit 1000 opens the screen unit 800 and transfers the high-pressure high air volume air from the separately installed blower (not shown) to the attached room or the evacuation stairway through the vertical wind, and the evacuation room or evacuation step room. Maintaining the air pressure at the positive air pressure indicates that fire smoke generated in the room can be prevented from leaking into the attached room or the evacuation stairs room. In the second embodiment of the present invention, the structure of the upper guide rail, the lower guide rail and the side guide rail has the same configuration as that of the first embodiment.

8 is a cross-sectional view of the side guide rail applied to the present invention. In FIG. 8, the side guide rails have a “c” shape, and both ends of the screen part 800 are inserted into the guide rails to slide upward and downward. Therefore, when the depth of the guide rail is maintained to some extent, leakage of smoke through the side of the guide rail can be reduced to a minimum, and the shape retaining film iron film 840-2 for preventing leakage to the inside of the side guide rails 820 and 820-1. ) Can effectively prevent smoke leakage.

9 is a detailed configuration of the tension control unit applied to the present invention. In FIG. 9, the tension control units 700 and 700-1 applied to the present invention are fastened to the wire ropes 660 and 660-1 inside the vertical wind speed 50, and the wire ropes 660 in the tension control unit. The tension support part 730 is fastened to the end of the structure, and a tension spring 720 surrounding the wire rope 660 is inserted into the lower part of the tension support part 730. Therefore, the tension adjusting unit 700 configured as described above has the spring 720 relaxed when the wire rope 660 is relaxed and the spring 720 contracts when the wire rope 660 shrinks so that the tension of the wire rope is constant. It can be maintained.

10 is a block diagram of a controller applied to the present invention. In FIG. 10, the control unit 950 of the controller 1200 applied to the present invention receives a fire signal from the fire detector 957 and receives an indoor pressure and a smoke control area received from an indoor pressure sensor 955 installed in the room. By comparing the internal pressure of the subroom received from the subroom pressure sensor 956 located in the subroom, the blower 958 is controlled so that the internal pressure of the subroom is maintained at a pressure of 40 Pa ~ 60 Pa compared to the indoor pressure. To supply air. In addition, the controller 950 controls the deceleration motor 500 by receiving a contact signal from the upper limit switch 850 and the lower limit switch 850-1 to control the air supply opening and closing of the screen unit 800. You can do it.

100, 500: reduction motor, 110: first chain gear,
115: rotating rod, 120: second chain gear,
130: first bearing part, 140: second bearing part,
180: opening and closing portion, 200, 800: screen portion,
210: first chain gear, 220: second chain gear,
310: limit switch, 400: vertical duct,
510, 510-1: bearing part, 520, 520-1: gear wheel,
550: shaft, 600, 600-1: counterweight,
600-2: Balance bar, 650, 650-1: Chain, 660, 660-1: Wire rope, 700, 700-1: Tension control part, 810: Upper guide rail, 820, 820-1: Side guide rail, 830: lower guide rail, 900, 900-1: pulley, 1000: air supply, 1100: masonry wall

Claims (10)

The air supply unit 1000 is installed in the masonry wall between the vertical air wind 50 and the vertical air and the auxiliary room configured inside the building, and is connected to the air supply unit 1000 by the blower through the air supply unit 1000 in case of fire. In the smoke control damper system of a building to pressurize and supply air to an accessory room, which is a ventilation area, to prevent smoke from leaking into the accessory room.
The ventilation control damper system of the building,
A deceleration motor 500 for transferring the screen unit 800 upward and downward to be installed in one side space of the vertical wind in order to open and close the air supply port 1000;
A controller 1200 for controlling the reduction motor;
A shaft (550) interlocked with the motor shaft for transmitting power of the reduction motor (500);
A pair of cog wheels 520 and 520-1 configured to rotate by a rotation of the shaft spaced apart from the shaft 550 by a predetermined distance;
A bearing part for supporting the shaft 550 to rotate on one side;
A pair of chains 650 and 650-1 that rotate in connection with the pair of gear wheels 520 and 520-1, and
A screen portion 800 on which one side of the pair of chains is fastened;
A pair of pulleys 900 and 900-1 fixedly installed at the bottom and assisting the vertical movement of the screen unit;
Balance weights 600 and 600-1 for facilitating vertical movement of the screen portion;
One side is fastened to the screen portion 800, respectively, the pair of pulleys (900, 900-1) are wound around each connect a pair of balance weights (600, 600-1) and the other side is the pair of chains (650, 650-1), each of which comprises wire ropes (660, 660-1) connected to each other.
The method of claim 1,
The smoke removal damper system of the building,
Smoke elimination damper system of the building characterized in that it further comprises a respective tension control unit (700, 700-1) on one side of each of the wire rope (660, 660-1).
The method of claim 1,
The smoke removal damper system of the building,
The building's ventilation damper system, characterized in that it further comprises a guide rail formed inside the air supply.
The method according to claim 2, wherein
The smoke removal damper system of the building,
A ventilation damper system for a building, characterized in that it further comprises a guide rail formed inside the air supply and the screen portion is inserted and sliding.
The method of claim 3,
The guide rails
A ventilation damper system for a building comprising an upper guide rail, a lower guide rail and a side guide rail.
The method of claim 5,
The guide rails
A smoke suppression system for a building, characterized by preventing a smoke from forming inside the shape-retaining film iron film to prevent smoke from leaking inside.
Air is supplied to an accessory chamber, which is a ventilation area connected to the air supply unit 1000 by a blower in the event of a fire, through the air supply unit 1000 formed in the masonry wall between the vertical air winder 50 and the vertical air conditioner configured inside the building. A dehumidification damper system in a building that pressurizes and prevents smoke from leaking into the annex.
The ventilation control damper system of the building,
A deceleration motor 500 which is installed in one side space of the vertical wind in order to open and close the air supply 1000 at a time;
A controller 1200 for controlling the reduction motor;
A shaft (550) interlocked with the motor shaft for transmitting power of the reduction motor (500);
A pair of cog wheels 520 and 520-1 configured to rotate by a rotation of the shaft spaced apart from the shaft 550 by a predetermined distance;
A bearing part for supporting the shaft 550 to rotate on one side;
A pair of chains 650 and 650-1 that rotate in connection with the pair of gear wheels 520 and 520-1, and
A screen portion 800 on which one side of the pair of chains is fastened;
A pulley 900 fixedly installed at a lower side to assist the vertical movement of the screen unit;
Wire ropes 660 and 660-1 having one side fastened to the other side of the pair of chains 650 and 650-1, respectively;
A balance bar 600-2 fastened between the other ends of the respective wire ropes 660 and 660-1;
The building is fastened to the center of the balance bar 600-2 and comprises a wire rope 660-2 fastened to the lower center of the screen portion 800 by winding the pulley 900 Ventilation damper system.
The method of claim 7, wherein
The ventilation control damper system of the building,
A dehumidification damper system for a building, characterized in that it further comprises a respective tension control unit (700, 700-1) on each side of the wire rope.
9. The method of claim 8,
The smoke removal damper system of the building,
And a screen rail formed inside the air supply port so that the screen part slides in the guide rail.
10. The method of claim 9,
The guide rails
A smoke suppression system for a building, comprising: a shape-retaining film iron film for preventing smoke leakage inward.

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