KR20200022272A - Fire damper for thermo-sensitivity and electrical operation - Google Patents

Abstract

The present invention provides a fireproof damper, which is thermo-sensitively and electrically operable, is repetitively usable even after a single usage, easily makes inspection for determining an operation failure, and automatically shuts off power as soon as the damper is operated to minimize a loss of public emergency power. According to a proper embodiment of the present invention, the fireproof damper thermo-sensitively and electrically operated comprises: a cylindrical damper housing; a circular valve installed in the middle inside the damper housing to open and close a circular passage of the damper housing; a spring for closing a valve having one end connected to the circular valve and the other end connected to the damper housing and installed to pull the circular valve in a closing direction by an elastic force; and a sensor assembly mounted in the damper housing to sense temperature of circular passage side flame heat through a shape memory alloy spring or to automatically close the circular valve, having been opened, by electrical application of the shape memory alloy spring when a fire occurs.

Description

Fire damper for thermo-sensitivity and electrical operation

The present invention relates to a fire damper, in particular, it can be thermally and electrically operated, can be used repeatedly after a single use, easy to check for malfunction of the operation, the power is automatically cut off at the same time as the damper operation It relates to a fire damper capable of minimizing non-public power loss.

In general, fire dampers are installed in ducts to block flames and smoke in case of fire. The fire damper detects a fire and closes the valve to block the propagation path of smoke and flame. In order to operate a fire damper, a fuse that melts when the temperature rises may be used. In this case, the fuse has a disadvantage that it cannot be used repeatedly once it is melted. In addition, since the fuse uses a physical melting phenomenon, it is difficult to safely inspect the fire damper. In order to solve this problem, the fuse may be removed and a shape memory alloy coil may be applied.

As a background technology of the present invention, Korean Utility Model Registration No. 20-0441364 has been proposed, 'Fire damper for wet-type air ducts with a guide throttle plate attached'. This allows the intermittent plate to be forcibly opened with a spring and then to maintain the opening force through the fuse. However, when a fire occurs, the fuse has a disadvantage that it cannot be repeatedly used once melted, and there is a problem that it is difficult to check the operation check.

Another background art of the present invention is Korean Patent Registration No. 10-1559862, 'Fire damper and fire damper operation method' has been proposed. When the shape memory alloy coil is thermally sensitive, it is contracted to overcome the spring force to maintain the opening and close the duct passage. The latter background, however, makes it difficult to balance the forces between the shape memory alloy coil and the elastic spring upon opening the duct passageway.

Korea Utility Model Registration No. 20-0441364 Korea Patent Registration No. 10-1559862

The present invention can operate thermally and electrically, can be repeatedly used even after a single use, easy to check for poor operation, and automatically shut off the power at the same time as the damper operation to minimize emergency power loss It is an object of the present invention to provide a fire damper.

A heat sensitive and electrically operated fire damper according to a preferred embodiment of the present invention includes a cylindrical damper housing; A circular valve rotatably installed in the middle of the damper housing to open and close a circular passage of the damper housing; A valve closing spring having one end connected to the circular valve and the other end connected to the damper housing and installed to pull the circular valve in the closing direction with elastic force; A sensor assembly mounted on the damper housing to sense the temperature of the flame passage on the circular passage side through a shape memory alloy spring or to automatically close the circular valve opened by electrical application of the shape memory alloy spring; It is done.

The sensor assembly may include: a sensor body having a latch stopper guide groove and supported and mounted on an outer circumferential surface side of the damper housing; A latch supported by the sensor body and installed to be movable in a direction perpendicular to the latch stopper guide groove; A latch spring for applying a force to push the latch toward the latch stopper guide groove; A latch cable having one end connected to the latch and the other end disposed on a circular passage of a damper housing; A shape memory alloy spring, one end of which is connected to the latch cable and the other end of which is supported by the damper housing side and thermally contracted by the flame opening detected in the circular passage to pull the latch cable; A latch stopper disposed in the latch stopper guide groove, the latch stopper having a latch catching groove which is latched and released according to a moving position; And a valve opening cable having one end connected to the circular valve and the other end exposed to the outside of the sensor body after being fixed by inserting the latch stopper.

In addition, the fire damper further includes a fire damper circuit to reduce the power load of the valve closing operation in the event of a fire and to check the valve operation if necessary. The fire damper circuit further includes a voltage having the same polarity even if a voltage of any polarity is input. A bridge rectifier for outputting the same; A micro switch connected to the output terminal of the bridge rectifier, the micro switch being on when the circular valve is opened and operating after the circular valve is closed; A DC step-down converter connected to the micro switch to lower and convert a DC voltage; A control unit connected to a DC step-down converter and performing functions of voltage detection, temperature detection, voice signal generation, and output voltage control; A voice signal amplifier for amplifying the voice signal generated by the controller; A speaker for sounding a final signal output from the voice signal amplifier; A power electronic switch connected to an output end of the micro switch so as to control a power applied to the shape memory alloy spring by a control signal of a controller with a pulse; A DC output terminal connected to the power electronic switch to supply a DC voltage to the shape memory alloy coil; A check input terminal connected to the DC step-down converter and connected to a DC + 12V, ground, and initialization terminal; And a temperature detector connected to the control unit to detect and detect the ambient temperature.

In the event of a fire, the controller checks the operation sequence, detects the ambient temperature through a temperature detector, obtains an output value, modulates the pulse width through the control operation of the power electronic switch, and supplies a DC to the shape memory alloy spring to close it. When the induction and closing of the circular valve is confirmed, the indicator light is made with the voice guidance, and if it is confirmed that the opening is repeated several times through the micro switch, it is characterized in that the failure indicator signal is turned on.

In addition, when external power is applied to the check input terminal to check the operation, when the operation check key is closed, the sensor detects the ambient temperature through the temperature detector to obtain an output value, and pulses the control operation of the power electronic switch. By modulating the width, DC is supplied to the shape memory alloy spring to induce the closing, and when the closing of the circular valve is confirmed, the indicator lights up with voice guidance, and if the opening is repeated several times through the micro switch, The failure indicator is characterized in that the lighting is made.

According to the heat-sensitive and electrically operated fire damper of the present invention, the automatic closing is performed by removing the force closing the circular valve through the latch by the heat-sensing of the shape memory alloy spring to quickly block the propagation path of smoke and flame. have. In addition, the shape memory alloy spring is connected to the electrical circuit to enable sequential control and to easily perform the operation check as necessary.

In addition, since the shape memory alloy spring can be reused even after a single fire, the fire damper can be repeatedly used without replacement.

In addition, it is possible to discriminate start number to several fire dampers in a building, thereby reducing peak power load, increasing the reliability of operation, and anticipating sensitive fire operation by pulse management control by temperature sensing. have.

In addition, the operation of the fire damper and the switching off operation at the same time the driving power is cut off to prevent malfunction, minimizing the use of emergency public power.

The following drawings attached in this specification are illustrative of the preferred embodiments of the present invention, and together with the detailed description of the invention serves to further understand the technical spirit of the present invention, the present invention is only to the matter described in the accompanying drawings It should not be construed as limited.
1 is a perspective view of a fire damper electrically operated in accordance with the present embodiment, a part of the damper housing is cut off, the sensor body upper cover is removed.
FIG. 2 is an exploded perspective view of the sensor assembly shown in FIG. 1.
3 is a perspective view showing a part of the exploded perspective view of FIG. 2 from another angle.
4A and 4B are state diagrams in which the fire damper of FIG. 1 is open.
5A and 5B are state diagrams in which the fire damper of FIG. 1 is closed during a fire or an operation check.
6 is a circuit configuration diagram of the fire damper applied to the present embodiment.
7 is a control flowchart illustrating the fire and operation of the fire damper according to the present embodiment.

In the following the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments presented are exemplary for a clear understanding of the present invention is not limited thereto.

1 to 4, the fire damper 10 according to the present invention is installed in a duct 5 for ventilation and cooling and heating of a building and is used to block a propagation path of smoke and flame. In particular, the fire damper 10 is operated in response to heat in the event of a fire and at the same time automatic power is cut to minimize the power loss for emergency. In addition, the fire dampers 10 are sequentially operated when a plurality of fire dampers 10 are installed to prevent a sudden current load. In addition, the fire damper 10 is supplied to an external power source to facilitate the operation check electrically.

The fire damper 10 is provided with a cylindrical damper housing 12 made of steel to be connected to the duct (5). A circular valve 14 is installed in the damper housing 12. As for the circular valve 14, the center axis | shaft 0 is rotatably provided in the middle of the internal circular passage 121 of the damper housing 12. As shown in FIG. Therefore, when the circular valve 14 forms a right angle with the direction of the central axis of the damper housing 12, the circular passage 121 is closed as shown in FIG. 5A, and when the circular valve 14 forms a direction parallel to the direction of the central axis, the circular passage 121 as shown in FIG. 4A. Opened). When the circular valve 14 completely closes the circular passage 121, the circular valve 14 is stopped by the protruding protrusion formed on the inner surface of the circular passage 121, so that rotation is no longer possible.

The circular valve 14 is installed to receive a closing force by the valve closing spring 16. The valve closing spring 16 is installed so that one end is connected to the circular valve 14 and the other end is connected to the damper housing 12 to pull the circular valve 14 in the closing direction with elastic force. At this time, the connecting end of the valve closing spring 16 connected to the damper housing 12 is disposed above the central axis of rotation (0) of the circular valve (14).

The sensor assembly 20 is mounted on the damper housing 12 side. The sensor assembly 20 may be mounted directly on the outer circumferential surface of the damper housing 12, or may be mounted using the connection bracket 13 in the middle as in the present embodiment. The sensor assembly 20 serves to automatically close the open circular valve 14 by contracting and sensitizing the temperature of the flame heat through the shape memory alloy spring 208 in case of fire. In addition, the sensor assembly 20 serves to automatically close the open circular valve 14 by contracting with an electrical application to the shape memory alloy spring 208 in case of fire. In this way, the sensor assembly 20 is configured to use the shape memory alloy spring 208 to close the valve by electrically operating as well as thermally sensitive.

The sensor assembly 20 has a latch stopper guide groove 202a and a sensor body 202 mounted and supported on the outer circumferential surface side of the damper housing 12, and a latch stopper guide groove supported on the sensor body 202 side. A latch 204 provided to be movable in a direction perpendicular to 202a, a latch spring 205 for applying a force to push the latch 204 toward the latch stopper guide groove 202a, and one end thereof to the latch 204. Connected to the latch cable 206 and the other end of which is disposed on the circular passage 121 of the damper housing 12, one end of which is connected to the latch cable 206, and the other end of which is supported on the damper housing 12 side so that the circular passage ( The shape memory alloy spring 208 which pulls the latch cable 206 by heat contraction by the flame open detected by 121 and the latch stopper guide groove 202a are disposed in the latch 204 according to the moving position to be caught and released. A latch stopper 210 having a latching groove 210a, and a latch After fixed by the shovel toppeo 210 and one end connected to the circular valve 14 and the other end comprises a sensor body 202 is exposed to the outside for the valve opening in the cable 212. Here, one end of the shape memory alloy spring 208 is connected to the latch cable 206 and the other end is connected to the spring support bracket 11 installed to be fixed to the inner surface of the damper housing 12 as shown in FIGS. Reference numeral '203' is a 'sensor body upper cover', '207' is a 'sensor body lower cover'.

When the fire damper 10 configured as described above pulls the valve opening cable 212 as shown in FIGS. 4A and 4B, the circular valve 14 is opened to overcome the force of the valve closing spring 16 to open the damper housing 12. The circular passage 121 of is opened. At this time, the valve closing spring 16 is elongated under tension and exerts a force for closing the circular valve 14 opened by the elastic restoring force.

By pulling the cable for opening the valve 212, the latch stopper 210 is moved backward and caught by the front end of the latch 204. At this time, even if the pulling force of the valve opening cable 212 is removed, since the latch stopper 210 is held at the front end of the latch 204 through the latch locking groove 210a, the circular valve 14 is closed. The open state is maintained even though the spring 16 is under tension.

In this state, when a fire occurs in a place where the fire damper 10 is installed and the fire heat passes through the damper housing 12, the shape memory alloy spring 208 suddenly heats up and contracts, whereby the latch cable ( As the latch 204 is pulled and retracted through the 206, the latch stopper 210 that has been caught by the latch 204 as shown in FIGS. 5A and 5B is released.

Therefore, by immediately releasing the valve opening cable 212 connected to the latch stopper 210, the force that opens the circular valve 14 is removed, thereby immediately turning by the valve closing spring 16 force The valve 14 is closed to close the circular passage 121 to block the propagation path of smoke and flame.

As described above, in case of fire, the fire damper 10 contracts immediately by the heat response of the shape memory alloy spring 208 to release the latch 204 and the latch stopper 210 to perform a fire protection function.

The fire damper 10 operated as described above is not used for a single use, but once the valve opening cable 212 is pulled out as shown in FIG. 4B after the operation, the latch stopper 210 returns to the latch 204. Since the circular valve 14 can be opened again because it is caught, and the shape memory alloy spring 208 is returned to its original state, it is possible to repeatedly use the heat-sensitive operation in case of fire.

Meanwhile, the fire damper 10 may further include a fire damper circuit 50 as shown in FIG. 6 so that the fire damper 10 may be electrically operated during a safety check as well as during a fire. Fire damper circuit 50 is configured to reduce the power load of the valve closing operation in the event of a fire and to easily check the valve operation check if necessary.

As shown in FIG. 6, the fire damper circuit 50 is connected to an output terminal of the bridge rectifier 502 and the bridge rectifier 502 which outputs the voltage of the same polarity even when a voltage of any polarity is input, and latches when the circular valve 14 is opened. A micro switch 504 mounted on the printed circuit board 500 of FIG. 3 so as to be turned on by touching the stopper 210 and to be turned off after the closed valve 14 is closed. A DC voltage converter 506 connected to the 504 to lower and convert a voltage of DC, and a DC voltage converter 506 to be connected to perform a function of voltage detection, temperature detection, voice signal generation, and output voltage control. A control unit 508, a voice signal amplifier 510 for amplifying the voice signal generated by the control unit 508, a speaker 512 for sounding the final signal output from the voice signal amplifier 510, and a micro switch. A control unit 508 connected to an output terminal of 504 A power electronic switch 514 for controlling a power supply by a control signal of a power supply; and a DC output terminal 516 connected to the power electronic switch 514 to supply a DC voltage to the shape memory alloy coil 208. ), A check input terminal 518 connected to the DC step-down converter 506 and connected to a DC + 12V, ground, and initialization terminal, and a temperature detector connected to the control unit 508 to detect and detect an ambient temperature of the damper ( 520).

The operation at the time of emergency (fire occurrence) of such a fire damper circuit 50 will be described with reference to the flowchart of FIG. 7.

First, when detecting a fire from the fire monitoring panel (not shown) and receiving emergency power (S10), the control unit 508 checks the operation sequence (S11), and then detects the ambient temperature through the temperature detector 520 (S12). ) To calculate an output value corresponding to the sensed temperature (S13). Here, the peak power load can be leveled according to the operation sequence, thereby reducing the sudden power consumption, thereby increasing the reliability of the operation.

Then, the pulse width is modulated (S14) through a control operation of the power electronic switch 514 to supply a direct current to the shape memory alloy spring 208 to perform the valve closing. At this time, when the direct current is supplied to the shape memory alloy spring 208, the heat shrinks to induce the closing of the circular valve (14).

Here, when it is confirmed that the circular valve 14 is closed (S15), the micro switch 504 is turned off to automatically cut off the input power (S16). At this time, the closed voice guidance and the closed indicator light are turned on.

This can prevent the malfunction of the fire damper 10, it can be expected to minimize the use of power for emergency public.

On the other hand, if it is confirmed (S19) that the predetermined time opened (S17) is repeated several times through the micro switch 504, and outputs a failure output signal (S20). For example, an alarm sounds in the speaker 512 due to a fault output signal or lights up a fault indicator.

On the other hand, it is a matter of course that the operation check can be performed through the same process by putting an external power source (S5) to the check input terminal 518 of FIG. In this process, if the operation check key does not confirm the closing button (S30), if the damper state is closed (S31) and closed, the guidance of the closing voice and the lighting of the closing indicator (S32) are made, and the opening is opened. The voice guidance and the indicator light are turned on (S33).

As described above, the fire damper 10 can block the propagation path of smoke and flames automatically by heat response by using the shape memory alloy spring 208, and the electric sequential control can be performed, and the operation check as necessary can be performed. It can be performed easily.

In addition, since the shape memory alloy spring 208 can be reused even after a single fire, the fire damper can be repeatedly used without replacement.

In addition, by differently assigning a start number to a plurality of fire dampers 10 in a building, it is possible to increase the reliability of operation by reducing the peak power load, and can be expected a sensitive fire protection operation by pulse management control by temperature sensing. .

In addition, the operation of the fire damper 10 can be prevented at the same time as the driving power is cut off, thereby minimizing the use of emergency public power.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The invention is not limited by the invention as such variations and modifications but only by the claims appended below.

12: damper housing
14: round valve
16: Valve closing spring
20: sensor assembly
202: sensor body
204: latch
205: latch spring
Latch cable
208: Shape Memory Alloy Spring
Latch stopper
212: cable for valve opening
50: fire damper circuit

Claims (5)

In the fire damper 10 is installed in the duct (5) for ventilation and cooling and heating of the building and used to block the propagation path of smoke and flame,
A cylindrical damper housing 12;
A circular valve (14) rotatably installed in the middle of the damper housing (12) to open and close the circular passage (121) of the damper housing (12);
A valve closing spring 16, one end of which is connected to the circular valve 14 and the other end of which is connected to the damper housing 12 to pull the circular valve 14 in the closing direction with an elastic force;
A circular valve mounted on the damper housing 12 to sense the temperature of the flame heat in the circular passage 121 side in case of fire through the shape memory alloy spring 208 or open by the electrical application of the shape memory alloy spring 208. A thermosensitive and electrically operated fire damper comprising: a sensor assembly 20 for automatically closing 14. The method of claim 1,
The sensor assembly 20,
A sensor body (202) having a latch stopper guide groove (202a) and supported and mounted on an outer circumferential surface side of the damper housing (12);
A latch 204 supported on the sensor body 202 and installed to be movable in a direction perpendicular to the latch stopper guide groove 202a;
A latch spring 205 for applying a force to push the latch 204 toward the latch stopper guide groove 202a;
A latch cable (206) having one end connected to the latch (204) and the other end disposed on the circular passage (121) of the damper housing (12);
A shape memory alloy spring 208, one end of which is connected to the latch cable 206 and the other end of which is supported by the damper housing side and thermally contracted by the flame heat detected by the circular passage 121 to pull the latch cable 206;
A latch stopper 210 disposed in the latch stopper guide groove 202a and having a latching groove 201a that is latched to and released from the latch 204 according to a moving position;
And a valve opening cable 212 having one end connected to the circular valve 14 and the other end exposed to the outside of the sensor body 202 after being fixed by inserting the latch stopper 210. Induction and electrically operated fire dampers. The method of claim 2,
The fire damper further includes a fire damper circuit 50 to reduce the power load of the valve closing operation in the event of a fire and to check the valve operation if necessary.
In the fire damper circuit 50,
A bridge rectifier 502 for outputting a voltage of the same polarity even if a voltage of any polarity is input;
A micro switch 504 connected to the output terminal of the bridge rectifier 502 to be turned on when the circular valve 14 is opened and to be turned off after the circular valve 14 is closed;
A DC step-down converter 506 connected to the micro switch 504 to lower and convert a DC voltage;
A control unit 508 connected to the DC step-down converter 506 to perform functions of voltage detection, temperature detection, voice signal generation, and output voltage control;
A voice signal amplifier 510 for amplifying the voice signal generated by the controller 508;
A speaker 512 for sounding the final signal output from the voice signal amplifier 510;
A power electronic switch 514 connected to an output end of the micro switch 504 to control pulses of power applied to the shape memory alloy spring 208 by a control signal of the controller 508;
A DC output terminal 516 connected to the power electronic switch 514 to supply a DC voltage to the shape memory alloy coil 208;
A check input terminal 518 connected to the DC step-down converter 506 and connected to a DC + 12V, ground, and initialization terminal;
A thermosensitive and electrically operated fire damper, comprising: a temperature detector 520 connected to the control unit 508 to detect and detect an ambient temperature. The method of claim 3, wherein
When the fire occurs, the control unit 508 checks the operation sequence, and then detects the ambient temperature through the temperature detector 520 to obtain an output value,
The pulse width is modulated through the control operation of the power electronic switch 514 to supply a direct current to the shape memory alloy spring 208 to induce closure.
When the closing of the circular valve 14 is confirmed, the indicator lights up with voice guidance, and if it is confirmed that the opening is repeated several times through the micro switch 504, the failure indicator signal is turned on. Fire-resistant and electrically operated fire damper. The method of claim 3, wherein
After confirming that the operation check key is closed after applying the external power to the check input terminal 518 to check the operation,
Detects the ambient temperature through the temperature detector 520 to obtain an output value,
The pulse width is modulated through the control operation of the power electronic switch 514 to supply a direct current to the shape memory alloy spring 208 to induce closure.
When the closing of the circular valve 14 is confirmed, the indicator light is turned on with voice guidance, and if the opening is repeated several times through the micro switch 504, the heat indicator is illuminated. And electrically operated fire dampers.

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