KR102386091B1 - The fireproof damper equipped with the insulation blocking plate - Google Patents

Abstract

The present invention relates to a fire damper equipped with an insulating barrier plate, and more particularly, in the event of a fire, it blocks the spread of ultra-high heat flame and heat from an ignition point through a duct pipe, and the blocking effect can be maintained for a predetermined time. By doing so, it is possible to delay or prevent the fire from spreading to adjacent buildings through the duct pipe, and also, the high heat of the damper outer frame heated by the superheated flame is quickly conducted to the lower area of the duct pipe, and inflammable substances around the damper The purpose of this invention is to provide a fire damper equipped with an insulating barrier that can prevent the fire from spreading out of control to an adjacent building as the fire spreads in the building.
In order to achieve the above object, the fire damper (1) having a thermal insulation barrier plate of the present invention has flanges facing outward and perpendicular to both ends of a tubular body made of iron or fire-resistant material of a predetermined thickness in a rectangular or circular cross-section. The formed outer frame 100 and; a thermal insulation blocking plate 200 installed inside the outer frame 100 to block the movement of high-temperature flame and heat that have penetrated into the duct pipe when a fire occurs; In the fire damper having a heat insulation blocking plate comprising; a fire-resisting insulation shell 300 wound on the outside of the outer frame 100 to maintain airtightness by a known coupling means and to be fixedly coupled, the outer frame ( 100) is characterized in that a series of heat conduction delay holes 150 are continuously provided at a predetermined interval through holes.
In addition, the heat conduction delay hole 150 of the fire damper having a heat insulation blocking plate of the present invention for achieving the above object is selected from the front area, the rear area, the center area, or the entire area of the outer frame 100 It is formed in any one area, characterized in that it is formed in one or more rows along the horizontal direction of the four sides of the outer frame (100).
According to the fire damper provided with the insulating barrier plate of the present invention configured as described above, in the event of a fire, the superheated flame and heat from the ignition point are prevented from spreading through the duct pipe, and the blocking effect can be maintained for a predetermined time. It is possible to prevent the fire from spreading and spreading to adjacent buildings through the duct pipe. Also, the high heat of the damper outer frame heated by the superheated flame is quickly conducted to the lower area of the duct pipe and causes fire to the flammable materials around the damper. A fire damper provided with an insulating barrier plate that can prevent the fire from spreading out of control to an adjacent building is provided.

Description

{The fireproof damper equipped with the insulation blocking plate}

The present invention relates to a fire damper equipped with a thermal barrier plate, and more particularly, blocks the spread of ultra-high heat flame and heat from an ignition point through a duct pipe when a fire occurs, and the blocking effect is maintained for a predetermined time It is possible to delay or prevent the fire from spreading to adjacent buildings through the duct pipe, and also, the high heat of the damper outer frame heated by the superheated flame is quickly conducted to the lower area of the duct pipe, and It relates to a fire damper equipped with an insulating barrier plate that can prevent the fire from spreading out of control to an adjacent building when a flammable material is ignited.

A fire damper is a pipe blocking device that is connected to the part where the duct, which is an air conditioning structure for ventilation, cooling, and heating of a building, passes through the fire zone or is close to it. It is a fire protection facility to block high heat and secure the initial evacuation time for people to evacuate quickly and safely from the fire site.

In general, when a fire occurs, the heat of the flame spread through the duct from the ignition area is estimated to exceed 1,000℃.

The above-mentioned ultra-high heat flame and heat can be blocked from spreading by the damper blocking plate installed in the middle of the duct, but due to the super high heat of the flame and heat, the damper’s steel blocking plate cannot endure for long and is bent. A crevice is created, and the flame spreads through the crevice, and the fire spreads to adjacent buildings.

In addition, the high heat of the damper outer frame heated by the ultra-high-temperature flame as described above is rapidly conducted to the lower area of the duct pipe, and the fire spreads out of control to adjacent buildings as the flammable materials around the damper are ignited.

Therefore, in order to prevent damage to human life from the fire site, the superheated flame and heat from the ignition point are blocked from spreading through the duct pipe, and the blocking effect is maintained for a predetermined time, so that the fire breaks the duct pipe. There is an urgent need for the appearance of a fire damper that can prevent it from spreading to adjacent buildings through the

In addition, the high heat of the damper outer frame heated by the superheated flame and heat is quickly conducted to the lower area of the duct pipe, and it is possible to prevent the fire from spreading out of control to adjacent buildings by igniting inflammable materials around the damper. There is an urgent need for the appearance of a fire damper.

1. Korea Patent Publication No. 20-1985-0007726, published on October 15, 1985, fire damper closed by temperature 2. Korea Patent Publication No. 10-1057010, registered on August 8, 2011, fire damper with back draft damper 3. Korean Utility Model Publication No. 20-0455704, registered on September 14, 2011, fire damper for air duct 4. Korea Patent Publication No. 10-1533333, registered on June 26, 2015, fire damper

The fire damper provided with a thermal barrier plate of the present invention devised to solve the above problems blocks the spread of super high heat flame and heat from the ignition point through the duct pipe when a fire occurs, and the blocking effect is maintained for a predetermined time. By making it possible to maintain, it is possible to delay or prevent the fire from spreading to adjacent buildings through the duct, and also, the high heat of the damper outer frame heated by the superheated flame is quickly conducted to the lower area of the duct and around the damper. An object of the present invention is to provide a fire damper equipped with an insulating barrier plate that can prevent the fire from spreading out of control to an adjacent building as the flammable material of the building catches fire.

In order to achieve the above object, the fire damper (1) having a thermal insulation barrier plate of the present invention has flanges facing outward and perpendicular to both ends of a tubular body made of iron or fire-resistant material of a predetermined thickness in a rectangular or circular cross-section. The formed outer frame 100 and; a thermal insulation blocking plate 200 installed inside the outer frame 100 to block the movement of high-temperature flame and heat that have penetrated into the duct pipe when a fire occurs; In the fire damper having a heat insulation blocking plate comprising; a fire-resisting insulation shell 300 wound on the outside of the outer frame 100 to maintain airtightness by a known coupling means and to be fixedly coupled, the outer frame ( 100) is characterized in that a series of heat conduction delay holes 150 are continuously provided at a predetermined interval through holes.
In addition, the heat conduction delay hole 150 of the fire damper having a heat insulation blocking plate of the present invention for achieving the above object is selected from the front area, the rear area, the center area, or the entire area of the outer frame 100 It is formed in any one area, characterized in that it is formed in one or more rows along the horizontal direction of the four sides of the outer frame (100).

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According to the fire damper provided with the insulating barrier plate of the present invention configured as described above, in the event of a fire, the superheated flame and heat from the ignition point are prevented from spreading through the duct pipe, and the blocking effect can be maintained for a predetermined time. It can prevent the fire from spreading and spreading to adjacent buildings through the duct, and also, the high heat of the damper outer frame heated by the superheated flame and heat is quickly conducted to the lower area of the duct, and inflammable substances around the damper A fire damper equipped with an insulating barrier that can prevent the fire from spreading out of control to the adjacent building as the fire spreads to the building will be provided.

1 is an explanatory view of a fire damper provided with a heat insulation block plate according to the present invention, and is an explanatory view illustrating a state in which the insulation block board is caught and fixed by a shape memory alloy iron wire.
Fig. 2 is an explanatory view showing the front of Fig. 1;
3 is a conceptual diagram of a fitting coupling of the present invention.
4 is an explanatory view showing another example of a fire damper provided with a heat insulation blocking plate according to the present invention.
Figure 5 is an explanatory view of the heat insulation blocking plate of the present invention.
Figure 6 (a) (b) shows another embodiment of Figure 5, (a) is an explanatory view in which the heat insulation barrier plate is formed of a hollow rectangular double-sided panel, (b) is the hollow of (a) It is an explanatory diagram explaining the state in which the part is filled with a refractory material.
7 is an explanatory view showing a state in which a fire-resisting insulation shell is coupled to the outside.
8 is an explanatory view showing a state in which the heat insulation blocking plate of the fire damper provided with the insulation blocking plate according to the present invention is blocked.
9 is an explanatory view for explaining a portion of a heat insulating blocker as showing a case in which the outer frame of the present invention is formed in a cylindrical shape.

Hereinafter, the fire damper (1) provided with the heat insulation blocking plate of the present invention will be described in detail.

Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention. Accordingly, since the embodiments described in the present specification are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, various equivalents and modifications that can be substituted for them at the time of filing of the present invention It should be understood that there may be examples. Also, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, in adding reference numerals to each component, it should be noted that the same components are marked with the same reference numerals and the same names as much as possible even though they are marked on different drawings.

1 is an explanatory view of a fire damper equipped with a heat insulation block plate according to the present invention, and is an explanatory view illustrating a state in which the heat insulation block board is caught and fixed by a shape memory alloy iron wire, and Figure 2 is an explanation showing the front of FIG. 3 is a conceptual diagram of the fitting of the present invention, FIG. 4 is an explanatory view showing another example of a fire damper provided with a heat insulating block plate according to the present invention, and FIG. 5 is an explanatory view of the heat insulation block board of the present invention 6 (a) (b) shows another embodiment of FIG. 5, (a) is an explanatory view in which the heat insulation barrier plate is formed of a hollow rectangular double-sided panel, (b) is (a) It is an explanatory view explaining the state in which the fireproof material is filled in the hollow part of the It is an explanatory view showing a state in which the heat insulation blocking plate is blocked, and FIG. 9 is an explanatory view for explaining the blocking plate part by showing a case in which the outer frame of the present invention is formed in a cylindrical shape.

1 to 9, the fire damper 1 having a heat insulation block plate according to the present invention for achieving the above object is made of iron or fire-resistant material of a predetermined thickness in a rectangular or circular cross-section. an outer frame 100 having flanges formed at right angles outwardly from both ends of the tubular body; a thermal insulation blocking plate 200 installed inside the outer frame 100 to block the movement of high-temperature flame and heat that have penetrated into the duct pipe when a fire occurs; In the fire damper having a heat insulation blocking plate comprising; a fire-resisting insulation shell 300 wound on the outside of the outer frame 100 to maintain airtightness by a known coupling means and to be fixedly coupled, the outer frame ( 100) is characterized in that a series of heat conduction delay holes 150 are continuously provided at a predetermined interval through holes.
In addition, the heat conduction delay hole 150 of the fire damper having a heat insulation blocking plate of the present invention for achieving the above object is selected from the front area, the rear area, the center area, or the entire area of the outer frame 100 It is formed in any one area, characterized in that it is formed in one or more rows along the horizontal direction of the four sides of the outer frame (100).

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Hereinafter, it will be described in more detail.

A fire damper is a pipe blockage facility in which a duct installed for ventilation, cooling, or heating of a building is connected to a part passing through a fire zone or a part adjacent thereto.

The fire damper serves to secure an initial evacuation time for people to quickly and safely evacuate from the fire site by blocking the flame or heat spreading through the duct when a fire occurs in the building.

The outer frame 100 of the fire damper 1 provided with the heat insulation blocking plate of the present invention is formed of a tubular body made of iron or fire-resistant material having a rectangular or circular cross-section and having a predetermined thickness.

However, since the outer frame 100 suffices as long as it is a cylindrical tubular body, there is no restriction on the cross-sectional shape.

However, since the fire damper (1) provided with the insulation barrier plate according to the present invention is connected to a predetermined position between the duct pipe and the duct pipe, the cross-sectional shape of the outer frame 100 is the same as the cross-sectional shape of the duct pipe. It will be advantageous for the convenience of the installation process to be formed in a shape.

Therefore, of course, the outer frame 100 may be formed in a cylindrical shape.

In this embodiment, for convenience of explanation, the outer frame 100 made of a tubular body having a rectangular cross-section as shown in FIG. 1 is illustrated, and the present embodiment will be described with reference to this.

At both ends of the outer frame 100, as shown in FIG. 1, flanges 110 of a predetermined width are welded outward and perpendicular to each other.

This is for the convenience of the coupling process when the flange 110 of the outer frame 100 and the flange of the duct pipe are coupled to each other by a known coupling method such as bolt fastening.

Accordingly, a width corresponding to the width of the flange 110 of the outer frame 100 will be sufficient as long as it corresponds to the width of the flange of the duct pipe.

The flange 110 is formed according to the above even in the case of the outer frame 100 formed of a circular cross-section or other tubular body.

In the upper center of the left and right sides of the outer frame 100, as shown in FIG. 1, each shaft fixing hole 102 is through, and the inside of the outer frame 100 is provided in the left and right side shaft fixing holes 102. Axes 101 are fixed across.

L-shaped female shims 131 and ♀ are welded to a predetermined point in the center of the bottom surface of the outer frame 100 .

The female shims 131 and ♀ are formed at the same points as above even when the outer frame 100 is formed of a cylindrical or other tubular body having a different cross-sectional shape.

The L-shaped female shims 131 and ♀ welded to a predetermined point in the center of the bottom surface of the outer frame 100 are the same as those shown in FIGS. 3 and 8 when the heat insulation blocking plate 200 is blocked. Similarly, the other surface of the insulating barrier plate 200 is fitted with a shim (204, ♂) fixed by welding to the central portion of the lower end.

In addition, at an arbitrary position in a predetermined region of one end of the outer frame 100, as shown in FIG. 1, a catch 140 for locking and fixing the shape memory alloy iron wire 220 is welded.

Next, on the four sides of the outer frame 100 , as shown in FIG. 1 , heat conduction delay holes 150 of a predetermined size may be sequentially formed with a predetermined interval therebetween.

The heat conduction delay hole 150 is a long hole that is long in the transverse direction, and is not limited by the shape, and the hole is in any shape, such as a round, oval, rectangular or long hole (a kind of long hole in one direction). It is possible.

The series of heat conduction delay holes 150 may be formed in any area selected from a predetermined area or the entire area of the four sides of the outer frame 100 .

That is, the series of delayed heat conduction holes 150 may be formed in any one region selected from the front region, the rear region, the central region, or the entire region of the outer frame 100 .

The heat conduction delay hole 150 may be formed in one or more rows in the horizontal direction of the four sides of the outer frame 100 .

However, when the series of delayed heat conduction holes 150 are formed in two or more rows with a predetermined interval, the delay or attenuation effect of heat conduction through the four sides of the outer frame 100 becomes larger.

1 shows a case in which one row of heat conduction delay holes 150 are formed in the front region of the outer frame 100 .

The heat conduction delay hole 150 is formed as described above even when the outer frame 100 is formed of a cylindrical or other tubular body having a different cross-sectional shape.

As described above, by forming a series of heat conduction delay holes 150 in the outer frame 100, when a fire occurs, the high heat of the damper outer frame 100 heated by the superheated flame and heat quickly moves to the lower area of the duct pipe. This prevents the fire from spreading out of control to adjacent buildings as the inflammable material around the damper is ignited and spreads, thereby securing the initial evacuation time for people to quickly escape from the fire scene.

Hereinafter, another embodiment of the fire damper outer frame 100 provided with a heat insulation blocking plate according to the present invention will be described in detail.
4 is an explanatory view showing another embodiment of the fire damper outer frame 100 provided with a heat insulation blocking plate according to the present invention.

The outer frame 100 of the fire damper 1 having the heat insulation blocking plate is in contact with the upper surface of the inner surface and the upper crossbar 120 is welded, and the lower crossbar 130 is welded in contact with the lower surface of the inner surface. there is.

The upper side of the heat insulation block plate 200 is hinged 210 to the upper cross bar 120 , and the lower cross bar 130 becomes a stopper when the heat insulation block plate 200 is blocked.

A female shim (131, ♀) is welded and fixed to one surface of the central part of the lower crosspiece (130).

At this time, when the heat insulation blocking plate 200 is blocked on the female shims 131, ♀, which are welded and fixed to one side of the central part of the lower crossbar 130, as shown in FIGS. 3 and 8, the insulation blocking plate ( 200), the shim (204, ♂) fixed by welding to the center of the lower end is fitted.

In addition, at a predetermined point on one end of the upper surface of the inner surface of the outer frame 100, as shown in FIG. 1, a locking member 140 capable of hanging the shape memory alloy iron wire 220 is welded and fixed.

In addition, on the four sides of the outer frame 100, the heat conduction delay holes 150 of a predetermined size are formed in one row sequentially at a predetermined interval.

It is of course possible that the heat conduction delay hole 150 is formed in two or more rows.

The configuration of another embodiment of the fire damper 1 having the above-described insulating blocking plate is the same even when the outer frame 100 is formed of a tubular body having a cylindrical shape and other shapes having different cross sections.

Next, the heat insulation blocking plate 200 will be described in detail.
The heat insulation blocking plate 200 is a pipe blocking plate installed inside the outer frame 100 to block the movement of high-temperature flame and heat penetrating into the duct pipe when a fire occurs.

The heat insulation blocking plate 200 is formed of a high heat-resistant iron plate having a predetermined thickness, and the left and right widths of the heat insulation block board 200 are formed to correspond to the left and right widths of the outer frame 100 .

When the outer frame 100 is formed of a tubular body having a cylindrical or other cross-section having a different shape, the insulation blocking plate 200 is formed in a shape corresponding to the shape of the tubular body.

A plurality of shaft coupling holes 203 are horizontally welded to an upper portion of one surface of the heat insulation blocking plate 200 , and the shaft coupling holes 203 are rotatably shafted to the shaft 101 of the outer frame 100 . are combined

In addition, in the central portion of the lower end of the other surface of the insulating blocking plate 200, as shown in FIG. 3, the shims (204, ♂) are welded and fixed.

As seen before, the L-shaped female shims 131 and ♀ are welded to a predetermined point in the center of the bottom surface of the outer frame 100, and are welded to the lower center of the other surface of the insulation blocking plate 200. The fixed shim (204, ♂) is welded to a predetermined point in the center of the bottom surface of the outer frame 100, as shown in FIGS. 3 and 8, when the heat insulation blocking plate 200 is blocked. It is fitted into the L-shaped female shim (131, ♀) that is joined.

The female shims (131, ♀) and the male shims (204, ♂) are formed in a tubular body in which the outer frame 100 is cylindrical and other shapes having different cross-sections, so that the insulation blocking plate 200 is corresponding thereto. Even when it is formed in a shape, it is formed according to the above.

Next, as shown in FIG. 1, the lower side 202 of the heat insulation blocking plate 200 is a shape memory alloy that is a locking hole in the locking member 140 that is welded and fixed to the upper one end region of the inner surface of the outer frame 100. It is caught and fixed to the wire 220.

The shape-memory alloy iron wire 220 is a metal wire having a property of remembering the shape before being deformed and returning to its previous shape when it reaches a predetermined shape memory temperature even if an artificial deformation is applied to it.

The shape memory alloy iron wire 220, which is a locking hole, has a shape before being transformed into a locking hole when the internal temperature of the duct tube reaches a predetermined shape memory temperature by the high heat flame and heat that has penetrated into the duct tube due to a fire. Remember, immediately return to the previous straight wire and release the jammed state, and the shim 204 welded to the center of the lower end of the insulation block 200 is set at the center of the bottom of the outer frame 100. It is fitted to the L-shaped female shim (131, ♀) welded to the point and blocks the pipe to block the movement of flame and heat that has penetrated into the duct pipe.

At this time, the insulation blocking plate 200 is attached to an arbitrary position of the outer frame 100 with a temperature sensing sensor (not shown) or a smoke sensing sensor (not shown), and is automatically blocked by interlocking with the detection result of each sensor. It is also possible to install as much as possible.

In particular, the smoke detection sensor (not shown) is installed to detect the concentration of smoke that has penetrated into the duct pipe at the initial stage of the fire and automatically cut off the insulation blocking plate 200 interlocked therewith, so that an early warning of a fire is provided. It is very useful for protecting people's lives and property.

On the other hand, when a fire occurs, the flame and high heat entering the duct pipe are known to exceed 1000°C.

Therefore, the insulation blocking plate 200 blocks the superheated flame and heat as described above, and only when the blocking state can be maintained for a predetermined time, people can evacuate from the fire site and save life.

However, in the event of a fire, due to the extremely high heat of the flame that has penetrated into the duct pipe, the damper’s steel barrier plate cannot withstand long and bends and creates a gap. It spreads to adjacent buildings.

In order to prevent this, the heat insulation blocking plate 200 is preferably formed of a hollow rectangular double-sided panel 200a in which a hollow part 230 is formed in the central part by welding and bonding the four sides of two high heat-resistant rectangular iron plates. Do.

By the effect of blocking or delaying heat conduction by the hollow part 230 of the hollow rectangular double-sided panel 200a of the insulation blocking plate 200, it blocks the movement of the ultra-high heat flame and heat penetrating into the duct pipe when a fire occurs. By delaying the time for maintaining the blocking effect, it is possible to secure an initial evacuation time for people to safely evacuate from the fire scene.

At this time, an air inlet hole 231 communicating with the hollow part 230 is provided at an arbitrary point on one side of the hollow rectangular double-sided panel 200a, which is the heat insulation blocking plate 200 .

It is possible to prevent damage due to thermal expansion of the hollow part 230 by the air in/out hole 231 .

In addition, at this time, filling the hollow part 230 with a refractory material 232 such as ceramic wool or glass wool can also increase the thermal insulation performance of the hollow rectangular double-sided panel 200a, which is the thermal insulation blocking plate 200. desirable.

Due to the effect of blocking or delaying heat conduction by the fireproof material 232 filled in the hollow part 230, when a fire occurs, the hollow rectangular double-sided panel 200a, which is the insulation blocking plate 200, penetrates into the duct pipe. It is possible to secure an initial evacuation time for people to safely evacuate from the fire site by blocking the movement of flame and heat or delaying the time for maintaining the blocking effect.

Even at this time, the air inlet hole 231 is provided at any point on one side of the hollow rectangular double-sided panel 200a, which is the heat insulation blocking plate 200 .

It is possible to prevent damage due to thermal expansion of the hollow part 230 by the air in/out hole 231 .

In addition, it is also preferable to attach a fireproof insulation material (not shown) of a predetermined width on one or both sides of the heat insulation blocking plate 200 .

Due to the effect of blocking or delaying heat conduction by a fireproof insulation material (not shown) of a predetermined width attached to one or both sides of the heat insulation block board 200, when a fire occurs, the heat insulation block board 200 is a duct pipe It is possible to secure the initial evacuation time for people to safely evacuate from the fire site by blocking the superheated flame and heat that have penetrated inside or delaying the time to maintain the blocking effect.

At this time, it is more preferable that the size of the fireproof insulation material (not shown) is formed as large as the size of the gap between the insulation blocking plate 200 and the inner surface of the outer frame 100 .

This is due to the small protrusions protruding from the four sides of the fire-resistant fabric material (not shown) attached to one or both sides of the heat-insulating blocking plate 200 when the heat-insulating blocking plate 200 is blocked ( This is because the packing effect is generated on the upper, lower and left and right sides of 200), and the blocking effect of the pipeline can be further increased.

In addition, the fire damper (1) provided with the heat insulation blocking plate of the present invention, when the outer frame 100 is formed of a tubular body having a cylindrical or other cross section of a different shape, the heat insulation blocking plate 200 is in the shape of the tubular body formed in a corresponding shape.

Therefore, when the outer frame 100 is formed in a cylindrical shape, the heat insulation blocking plate 200 is also formed in a disk shape corresponding to the shape.

The accompanying FIG. 9 is an explanatory view for explaining a portion of the heat insulation blocking plate 200 as showing a case in which the outer frame of the present invention is formed in a cylindrical shape.

The disk-shaped heat insulation blocking plate 200, the shaft 101 is coupled to the central portion, and both ends of the shaft 101 are rotatably in the shaft fixing hole 102 through the inner surface of the cylindrical outer frame 100 on both sides. Fixed, one wing 241 is tensioned by a tension spring 250 fixed to one inner surface of the outer frame 100 , and the other wing 242 is a take-over wire 260 fixed to one inner surface of the outer frame 100 . ), the pipeline is opened, and a fuse 270 is interposed in the central portion of the takeover wire 260 .

Even at this time, the shim 204 is welded to the lower central portion of the lower surface of the disk-shaped insulating blocking plate 200 .

Of course, L-shaped female shims 131 and ♀ are welded to a predetermined point in the center of the bottom surface of the outer frame 100 .

When a fire occurs, when the temperature of the flame and heat penetrated into the duct pipe exceeds the melting temperature of the fuse 270 , the fuse 270 is melted and the takeover wire 260 releases the takeover of the other wing 242 to one side. By the tensile force of the tensile spring 250 tensioning the wing 241, the disk-shaped heat insulation blocking plate 200 is pulled and rotated, and the outer frame 100 is welded to the lower center portion of the lower end of the shim 204. ), it is fitted with a L-shaped female shim (131, ♀) welded to a predetermined point in the center of the bottom surface and blocks the pipe to block the movement of flame and heat penetrating into the duct pipe.

On the outside of the outer frame 100 formed as described above, as shown in FIG. 4 , a fire-resistance insulation shell 300 is wound to maintain airtightness by a known coupling means and to be coupled and fixed by the present invention. The configuration of the fire damper (1) is completed.

By the fire damper (1) provided with the insulation barrier plate of the present invention configured as described above, in the event of a fire, the movement of flame, heat, and smoke that has penetrated into the duct pipe is blocked or attenuated, so that the fire is transmitted to the adjacent building through the duct pipe. Since it can prevent the spread of the fire in advance, it can greatly contribute to minimizing damage to life and property by securing the initial evacuation time of people from the fire site.

Hereinafter, the operation of the fire damper (1) provided with a heat insulation blocking plate according to the present invention will be described in detail.

First, the flange 110 is welded to the outside of both ends of the tubular body made of iron or fire-resistant material of a predetermined thickness in a rectangular or circular cross-section, and the shaft fixing hole 102 is through-hole in the upper left and right sides to fix the shaft A shaft 101 is fixed to the ball 102, and a L-shaped shim (131, ♀) is welded to a predetermined point in the center of the bottom surface, and a shape memory alloy iron wire 220 is attached to an arbitrary position in a predetermined area of one end. The latch 140 for fixing the latch is welded, and the heat conduction delay hole 150 of a predetermined size is formed in one row sequentially in one row at a predetermined interval in a selected area of the four sides to form an outer frame 100. do.

Alternatively, the flange 110 is welded to the outside of both ends of the tubular body made of iron or fire-resistant material of a predetermined thickness having a rectangular or circular cross section, and the upper crossbar 120 is welded in contact with the upper surface of the inner surface, and the inner surface The lower crossbar 130 is welded in contact with the lower crossbar 130, and the female shims 131 and ♀ are welded and fixed to the central portion of one surface of the lower crosspiece 130, and at a predetermined point on the upper surface of the inner surface of one end, a shape memory alloy iron wire ( 220) is fixed by welding, and in a selected area of four sides, a heat conduction delay hole 150 of a predetermined size is sequentially formed in one row at a predetermined interval. can also be formed.

At this time, in both side regions of one side of the upper crossbar 120, the upper side 201 of the heat insulation blocking plate 200 is coupled with a hinge 210, and the lower side 202 is caught by a shape memory alloy iron wire 220 that is a locking hole. It is caught and fixed to the stopper 140 that is welded and fixed to the inner surface of the upper surface one end region.

Next, it is formed of a rectangular high heat-resistant iron plate having a predetermined thickness, and the left and right widths are formed to correspond to the left and right widths of the outer frame 100 , and a plurality of shaft coupling holes 203 are welded to the upper part of one surface, and the shaft coupling is performed. The ball 203 is rotatably shaft-coupled to the shaft 101 of the outer frame 100, and on the center of the lower end area on the other side, the shims (204, ♂) are welded and fixed, and the lower side 202 is a locking hole shape. It is caught on the memory alloy iron wire 220 to form a heat-insulating blocking plate 200 that is caught and fixed to the stopper 140 that is welded and fixed to the upper surface one end area of the inner surface of the outer frame 100 .

Alternatively, the heat insulation blocking plate 200 is a hollow rectangular shape in which four sides of two high heat-resistant rectangular iron plates are welded and bonded to form a hollow part 230 in the central part, and an air inlet hole 231 is penetrated at an arbitrary point on one surface. It is formed of a double-sided panel 200a, the left and right widths are formed to correspond to the left and right widths of the outer frame 100, and a plurality of shaft coupling holes 203 are welded to the top of one surface so that the shaft coupling holes 203 are formed in the outer frame. It is rotatably shaft-coupled to the shaft 101 of the frame 100, and on the center of the lower region of the other surface, a shim (204, ♂) is welded and fixed, and the lower side 202 is a shape memory alloy iron wire 220 that is a locking hole. It is also possible to form a heat insulating blocking plate 200 that is caught and fixed to the stopper 140 that is welded and fixed to the upper surface end region of the inner surface of the outer frame 100 .

The hollow part 230 may be filled with a refractory material 232 .

Alternatively, the heat insulation blocking plate 200, on one or both sides, a fireproof insulation material (not shown) of a predetermined width formed as large as the size of the gap with the inner surface of the outer frame 100 is attached, one surface A plurality of shaft coupling holes 203 are horizontally welded to the upper portion, so that the shaft coupling holes 203 are rotatably coupled to the shaft 101 of the outer frame 100, and the other surface is fitted in the center of the lower region. The iron (204, ♂) is welded and fixed, and the lower side 202 is caught on the shape memory alloy wire 220, which is the locking hole, and is caught by the locking member 140 that is welded and fixed to the upper surface one end area of the inner surface of the outer frame 100. It is also possible to form a fixed heat insulation blocking plate (200).

Next, as shown in FIG. 7 , on the outside of the outer frame 100 in which the heat insulation blocking plate 200 is hooked and fixed inside the outer frame 100, a fire-resisting insulation shell 300 is wound to the outside and is a known combination. The configuration of the fire damper (1) provided with the heat insulation blocking plate according to the present invention is completed by maintaining the airtightness by means of coupling and fixing.

According to the fire damper 1 provided with the insulation blocking plate configured as described above, due to a series of heat conduction delay holes 150 formed in the outer frame 100, the high heat of the flame when a fire occurs is the outer frame 100. By delaying or attenuating the conduction phenomenon that is conducted directly to the rear of the duct pipe through the four sides of the outer frame 100, it is possible to prevent the spread of fire due to direct conduction from the four sides of the outer frame 100. It is possible to prevent casualties by securing the initial evacuation time to escape.

In addition, according to the fire damper 1 provided with the insulating blocking plate configured as described above, the temperature inside the duct pipe reaches a predetermined shape memory temperature by the high-temperature flame and heat that has penetrated into the duct pipe after a fire is generated. When it is, the shape memory alloy iron wire 220, which is a locking hole, remembers the shape before being deformed into a locking hole, immediately returns to the previous straight wire, and the locking state is released, and the insulation blocking plate 200 is as shown in FIG. Similarly (⇒ indicates the direction of the fire spread), the lower end of the shim 204 welded to the center of the lower end is welded to a predetermined point in the center of the bottom of the outer frame 100. It is fitted to the female shim (131, ♀) and blocks the pipe to block the movement of the flame and heat penetrating into the duct pipe.

In addition, a hollow rectangular shape formed by welding and bonding the four sides of two high heat-resistant rectangular iron plates to the fire damper (1) equipped with the present invention, a fire damper (1), with a hollow part 230 in the center. The size of the gap between the double-sided panel 200a, the hollow part 230 by filling the fire resistant material 232, or the heat insulating blocking plate 200 on one or both sides of the outer frame 100 and the inner surface When it is formed by attaching a fireproof insulation material (not shown) of a predetermined width formed as large as possible, in the event of a fire, the superheated flame and heat that have penetrated into the duct pipe from the ignition point are blocked and the blocking effect is predetermined. This can be maintained for a period of time, preventing the fire from spreading through the duct to adjacent buildings.

Although the above-mentioned preferred embodiment has been described in detail with respect to the fire damper 1 provided with the heat insulating board of the present invention, it is always possible to apply various modifications or variations without departing from the spirit and scope of the present invention. . Accordingly, it is extremely obvious that the appended claims are intended to cover modifications and variations that fall within the scope of the present invention.

1 Fire damper equipped with a thermal barrier plate
100 Outer frame 101 Shaft 102 Shaft fixing hole 110 Flange
120 Upper crossbar 130 Lower crossbar 131 Female shim 140 Clamp 150 Heat conduction delay work
200 Insulation barrier 200' hollow rectangular double-sided panel 201 Upper side 202 Lower side
203 Shaft coupling hole 204 Shim
210 Hinge 220 Shape memory alloy wire 230 Hollow part 231 Air inlet hole 232 Fireproof material
241 One wing 242 The other wing 250 Tension spring 260 Trip wire 270 Fuse
300 fireproof insulation

Claims (13)

an outer frame 100 in which flanges are formed at right angles outward to both ends of a tubular body made of iron or fire-resistant material of a predetermined thickness in a rectangular or circular cross-section; a thermal insulation blocking plate 200 installed inside the outer frame 100 to block the movement of high-temperature flame and heat that have penetrated into the duct pipe when a fire occurs; In the fire damper having a heat insulation blocking plate comprising; a fire-resisting insulation shell 300 wound on the outside of the outer frame 100 to maintain airtightness by a known coupling means and to be fixedly coupled, the outer frame ( 100), a fire damper provided with a heat insulation blocking plate, characterized in that a series of heat conduction delay holes 150 in succession at a predetermined interval are passed through. According to claim 1, wherein the heat conduction delay hole 150 of the fire damper provided with the heat insulation blocking plate is formed in any one area selected from the front area, the rear area, the central area, and the entire area of the outer frame (100). However, a fire damper having a heat insulation blocking plate, characterized in that it is formed in one or more rows along the horizontal direction of the four sides of the outer frame (100). delete delete delete delete delete delete delete delete delete delete delete

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