KR102279457B1 - Installation Method of Insulation Duct using Fiber-resistant Duct Unit - Google Patents

Abstract

The present invention relates to a fiber refractory material duct pipe unit and a method for installing an insulating duct using the same, and more particularly, by connecting the unitary duct pipe units to form an overall duct pipe, storage and transport are easy, workability is excellent, and flame retardancy It relates to a fiber refractory material duct tube unit that can significantly improve and heat insulation performance and can effectively block flame spread in case of fire, and a method for installing an insulation duct using the same
The fiber refractory duct pipe unit 1 of the present invention for achieving the above object is formed of iron or reinforcing material, and the front frame 110 of a hollow square shape, and the front frame 110 are the same size. And to connect the rear frame 120 and the front and rear frames 110 and 120 of the same shape, each connection part 111, 121 of the front and rear frames 110 and 120, the inner side of the four ears Including four connecting bars 130 coupled to the front and rear frames 110, 120 and four connecting bars 140 coupled to the inner central point of each of the connecting parts 111 and 121 of the four sides a duct frame unit 100 configured as a duct to maintain the skeleton of the duct; The outside of the semi-non-combustible insulation 310 made of any one of rectangular ceramic wool, glass wool, or silica gel of a predetermined thickness that is wrapped around and coupled to the outside of the duct frame unit 100 to form a duct pipe A fire-resistant fiber sheet 300 of a predetermined thickness formed by wrapping with any one of a fire-resistant material 320 of Hwacheon or a glass film; The duct frame unit 100 is formed with a length that can wrap the outer periphery of the fiber refractory sheet 300 surrounded and in contact with the outside of the region between the front and rear outward flange portions 112 and 122 of the duct frame unit 100, the coupling bolt (b) ) through the fibrous refractory sheet 300 and bolted to the front and rear rims 110 and 120 connection parts 111 and 121 of the duct frame unit 100, the fibrous refractory sheet 300 In the fiber-resistant duct pipe unit comprising; a fixing frame 400 for firmly coupling and fixing the to the outside of the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100, the In the middle region of the duct frame unit 100, it is formed in a cross shape made of a flame retardant or flame retardant material to form a nut hole n at each cross end, and a connecting bar 130 inside the duct frame unit 100 and The inner reinforcing bar 210 located in the center of the connecting bar 140, and a nut hole n at a point corresponding to each cross end of the inner reinforcing bar 210 is formed of an iron piece or a reinforcing material of a predetermined length. The connecting bar 130 at a position corresponding to the inner reinforcing bar 210 and the outer reinforcing bar 220 wound around the outside of the connecting bar 140 are nut formed on the outer reinforcing bar 220 by the coupling bolt (b). A support structure 200 that is bolted and fixed to each nut hole n formed at each cross end of the cross-shaped inner reinforcing bar 210 through the ball n to increase the supporting strength for wind pressure and air volume inside the duct pipe (200) characterized in that it is provided.
In addition, the duct frame unit 100 of the fiber refractory duct pipe unit 1 of the present invention for achieving the above object is a protrusion of the preceding duct frame unit 100 when the duct frame unit 100 is connected between the duct frame units 100. The connecting bar 130 and the connecting rod 140 are inserted and coupled to the inlet (not shown) of the trailing duct frame unit 100 to increase the bonding strength between the line and the trailing duct frame unit 100 (not shown). By inserting and coupling a predetermined width into the connecting portion 111 of the front rim 110, an inlet (not shown) is formed inside the connecting portion 111 of the front rim 110, and the rear rim 120 of It is characterized in that a protrusion (not shown) is formed outside the connection part 121 .
According to the fiber refractory duct pipe unit of the present invention and the method for installing an insulating duct using the same of the present invention as described above, it is easy to store and transport, has excellent constructability, and has excellent thermal insulation performance, thereby preventing the risk of fire in advance. Since no noise is generated at the start or end of operation, the cause of civil complaints is eliminated, and it is very economical in terms of production cost due to its low cost. In case of a fire, if the flame flows into the duct pipe, it quickly blocks the duct pipe to prevent flame spread A fiber refractory material duct pipe unit and a method for installing an insulated duct using the same are provided.

Description

Fiber-resistant duct pipe unit and insulation duct installation method using the same {Installation Method of Insulation Duct using Fiber-resistant Duct Unit}

The present invention relates to a fiber refractory material duct pipe unit and a method for installing an insulating duct using the same, and more particularly, by connecting the unitary duct pipe units to form an overall duct pipe, storage and transport are easy, workability is excellent, and flame retardancy It relates to a fiber refractory material duct pipe unit that can significantly improve and heat insulation performance and can effectively block flame spread in the event of a fire, and a method for installing an insulation duct using the same.

In the kitchens of homes, restaurants, and school cafeterias, heat is always used to boil water and cook, so there is a lot of heat and smell of food.

Duct refers to a pipe for sending and ventilating air or gas for discharging such heat and odor to the outside, and is also called a wind duct or wind duct.

Ducts include low-speed ducts (wind speed 15 m/s) and high-speed ducts depending on the flow velocity of the gas, and are manufactured and supplied as square ducts and round ducts depending on the cross-sectional shape.

The material of the duct is generally a zinc iron plate, and in addition, it is made of various materials depending on the purpose of use, such as plastic, aluminum, and stainless steel plate, and it is common to insulate the outer surface with an insulating material.

The conventional ducts as described above are usually supplied with a length of 1400 mm, so the volume is very large, so there is a problem in storage or transportation to the construction site. Due to the long length, workability is greatly reduced at the construction site.

In addition, in order to prevent the movement of heat due to the temperature difference between the air flowing inside the duct and the outside of the duct, and to reduce the risk of fire, an insulating material is wound around the outside of the duct. The risk of fire was growing, especially in the case of plastic materials.

Also, in the case of ducts made of galvanized iron, when the blower installed at the end of the duct starts to operate, a negative pressure is temporarily formed in the pipe due to the strong suction force of the blower, There was a very loud roaring noise when the blower was finished, and even when the blower was shut down, the flow of air that was continuously flowing in the pipe was suddenly pushed toward the end of the duct pipe where the blower was installed due to inertia, and the roaring noise generated when the crushed zinc iron plate was pushed out and unfolded. This was very large, providing an excuse for complaints caused by noise.

In addition, in the case of a stainless material, the cost is relatively high and has a large impact on the production cost, so it is not economical.

In addition, since the carbide (oil residue) accumulated in the food cooking process is stuck inside the ventilation duct that discharges smoke, even a small spark can catch fire in an instant, and in case of a fire, the flame spreads through the duct pipe. It spreads rapidly to the entire building along the road, and the entire building is engulfed in flames, which can lead to large-scale human casualties, so it is of utmost importance to extinguish the fire at an early stage.

Conventionally, a fire damper (fd, fire damper) having a structure that opens and closes a duct pipe by the elasticity of a spring that has been installed while melting a fuse when the temperature rises has been proposed.

The conventional fire damper as described above is generally composed of a spring and a small lead tag, and the lead piece (damper fuse) has reached a melting temperature of 75 degrees Celsius by the flame passing through the duct. It was designed to block the passage of the duct by closing the blocking plate with the force of the spring as the lead melts.

However, the conventional fire damper as described above takes a long time to melt the lead fuse, so it is often useless because the cut-off plate comes down after the flame has already spread through the duct pipe, and when the cut-off plate comes down to block the flame Due to the relaxation phenomenon of the Edo bullet spring, the blocking plate rattled and there was a gap, and the flame blocking effect was inevitably insufficient.

In addition, the conventional fire damper was proposed to be installed in the field by separately manufacturing the blocking member and the duct member, and thus the installation process was cumbersome, impairing work efficiency.

In addition, even after the fire is extinguished, it is difficult to check whether the blocking plate inside the duct is closed, so it is inconvenient to find out whether the blocking plate is open or closed for the entire duct pipe.

Korea Registered Utility Model No. 20-0357332 (Registered on July 23, 2004), FRP duct molded by filament winding method Korean Utility Model Registration No. 20-0455704 (Registered on September 14, 2011), Fire Damper for Air Duct Korean Patent Registration No. 10-1842398 (Registered on March 20, 2018), Duct connector including packing Korea Registered Utility Model No. 20-0492683 (Registered on November 18, 2020), Duct

The present invention has been devised to solve the above problems, and it is easy to store and transport, excellent in constructability, and excellent in insulation performance, so that the risk of fire is prevented in advance, and the operation of the blower installed at the end is started or Since there is no noise at the end of operation, the cause of civil complaints is eliminated, and it is very economical in terms of production cost as it is low cost. An object of the present invention is to provide a fiber refractory material duct pipe unit and a method for installing an insulating duct using the same.

The fiber refractory duct pipe unit 1 of the present invention for achieving the above object is formed of iron or reinforcing material, and the front frame 110 of a hollow square shape, and the front frame 110 are the same size. And to connect the rear frame 120 and the front and rear frames 110 and 120 of the same shape, each connection part 111, 121 of the front and rear frames 110 and 120, the inner side of the four ears Including four connecting bars 130 coupled to the front and rear frames 110, 120 and four connecting bars 140 coupled to the inner central point of each of the connecting parts 111 and 121 of the four sides a duct frame unit 100 configured as a duct to maintain the skeleton of the duct; The outside of the semi-non-combustible insulation 310 made of any one of rectangular ceramic wool, glass wool, or silica gel of a predetermined thickness that is wrapped around and coupled to the outside of the duct frame unit 100 to form a duct pipe A fire-resistant fiber sheet 300 of a predetermined thickness formed by wrapping with any one of a fire-resistant material 320 of Hwacheon or a glass film; The duct frame unit 100 is formed with a length that can wrap the outer periphery of the fiber refractory sheet 300 surrounded and in contact with the outside of the region between the front and rear outward flange portions 112 and 122 of the duct frame unit 100, the coupling bolt (b) ) through the fibrous refractory sheet 300 and bolted to the front and rear rims 110 and 120 connection parts 111 and 121 of the duct frame unit 100, the fibrous refractory sheet 300 In the fiber-resistant duct pipe unit comprising; a fixing frame 400 for firmly coupling and fixing the to the outside of the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100, the In the middle region of the duct frame unit 100, it is formed in a cross shape made of a flame retardant or flame retardant material to form a nut hole n at each cross end, and a connecting bar 130 inside the duct frame unit 100 and The inner reinforcing bar 210 located in the center of the connecting bar 140, and a nut hole n at a point corresponding to each cross end of the inner reinforcing bar 210 is formed of an iron piece or a reinforcing material of a predetermined length. The connecting bar 130 at a position corresponding to the inner reinforcing bar 210 and the outer reinforcing bar 220 wound around the outside of the connecting bar 140 are nut formed on the outer reinforcing bar 220 by the coupling bolt (b). A support structure 200 that is bolted and fixed to each nut hole n formed at each cross end of the cross-shaped inner reinforcing bar 210 through the ball n to increase the supporting strength for wind pressure and air volume inside the duct pipe (200) characterized in that it is provided.
In addition, the duct frame unit 100 of the fiber refractory duct pipe unit 1 of the present invention for achieving the above object is a protrusion of the preceding duct frame unit 100 when the duct frame unit 100 is connected between the duct frame units 100. The connecting bar 130 and the connecting rod 140 are inserted and coupled to the inlet (not shown) of the trailing duct frame unit 100 to increase the bonding strength between the line and the trailing duct frame unit 100 (not shown). By inserting and coupling a predetermined width into the connecting portion 111 of the front rim 110, an inlet (not shown) is formed inside the connecting portion 111 of the front rim 110, and the rear rim 120 of It is characterized in that a protrusion (not shown) is formed outside the connection part 121 .

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According to the fiber refractory duct pipe unit of the present invention and the method for installing an insulating duct using the same of the present invention as described above, it is easy to store and transport, has excellent constructability, and has excellent thermal insulation performance, thereby preventing the risk of fire in advance. Since no noise is generated at the start or end of operation, the cause of civil complaints is eliminated, and it is very economical in terms of production cost due to its low cost. In case of a fire, if the flame flows into the duct pipe, it quickly blocks the duct pipe to prevent flame spread A fiber refractory material duct pipe unit and a method for installing an insulated duct using the same are provided.

1 is an explanatory view of the formation process of the duct frame unit body 100 of the fibrous fire resistant duct pipe unit 1 of the present invention.
2 is a view showing the coupling of the branch wire connection structure 150 to one surface of the duct frame unit body (100).
3 is an explanatory view of the reinforcing material 210 coupled to the inner central portion of the duct frame unit 100 .
4 is an explanatory view of the duct frame unit 100A combined with the support structure, which is formed by combining the outer reinforcing material 220 from the outside of the inner reinforcing material 210 of the duct frame unit body 100 .
5 is an explanatory view of the fiber refractory material sheet 300 .
6 is a fibrous refractory duct unit of the present invention formed by bonding the fibrous refractory sheet 300 of FIG. 5 to the outside of the duct frame unit 100A combining the support structure of FIG. 4 and fixing it with a fixing frame 400 ( 1) is an explanatory diagram.
7 is a view for explaining the assembly (D) composed of two and one set of the fiber refractory duct pipe unit (1) of FIG. 6, and shows only the frame of the assembly (D) for convenience of understanding.
8 is a view for explaining a state in which the fiber-resistant duct unit (1) and its combination (D) are connected in series to install a duct suitable for the length of the duct installation location, and for convenience of understanding, the fiber-resistant duct pipe Only the frame of the unit (1) and its combination (D) is shown.
9 is a view for explaining the fibrous fire-resistance duct pipe unit 1 ′ for installing a curved part, and is a view showing only the frame for convenience of understanding.
10 is a view for explaining the assembly (D') composed of two and one set of fibrous fire-resisting duct pipe units (1') for installation in a curved portion, and shows only the frame of the assembly (D') for convenience of understanding.
11 is a flow chart of a method for installing an insulating duct using the fibrous fire-resistance duct pipe unit (1).
Fig. 12 is an explanatory view of a duct frame unit body 100C provided with a flame diffusion barrier.
Fig. 13 is an explanatory view for explaining the flame cut-off state of the duct frame unit body 100C provided with the flame spread cutoff port.
Fig. 14 is an explanatory view for explaining a state in which a duct pipe is installed through a wall (W) of a building.

Hereinafter, with reference to the accompanying drawings, the present invention, the fiber refractory material duct pipe unit (1) and the insulated duct installation method (2) using the same 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 their ordinary 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, the embodiments described in the present specification are only the most preferred embodiments of the present invention, and the technical spirit of the present invention Since it does not represent all of them, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing of the present invention. 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 the respective components, 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 displayed on different drawings.

Ducts are generally square, rectangular, or circular in cross-section, but it is of course possible to form ducts of various other shapes. In this embodiment, the present invention will be described by taking the case of a duct having a square cross-section, which is one of the squares, as an embodiment.

1 is an explanatory view of the formation process of the duct frame unit of the fiber refractory duct pipe unit of the present invention, and FIG. 2 is a view showing the connection of a branch wire connection structure to one surface of the duct frame unit, FIG. 3 is the duct frame It is an explanatory view of an inner reinforcing material coupled to the inner central portion of the unit, and FIG. 4 is an explanatory view of a duct frame unit 100A combining a support structure formed by combining an outer reinforcing material from the outside of the inner reinforcing material of the duct frame unit. is an explanatory view of the fibrous refractory sheet 300, FIG. 6 is a duct frame unit 100A combined with the support structure of FIG. 4, the fibrous refractory sheet 300 of FIG. 5 is combined with a fixing frame 400 It is an explanatory view of the fiber refractory duct pipe unit 1 of the present invention formed by fixing, and FIG. 7 is a view for explaining the assembly (D) composed of two sets of the fiber refractory duct pipe unit 1 of FIG. 6 For convenience of understanding, it is a view showing only the frame of the assembly (D), and FIG. 8 is a duct that matches the length of the duct installation location by connecting the fiber-resistant duct pipe unit (1) and the assembly (D) one after another. As a drawing for explaining one state, for the convenience of understanding, only the frame of the fiber refractory duct unit (1) and its combination (D) is shown, and FIG. 9 is a fiber refractory duct pipe unit (1') for installation in a curved part. As a drawing for explanation, it is a view showing only the frame for the convenience of understanding, and FIG. 10 is a view for explaining the assembly (D') composed of two sets of fibrous fire-resistance duct pipe units (1') for installing curved parts, D ') only the frame is shown, Figure 11 is a flow chart of a method for installing an insulated duct using a fiber-resistant duct pipe unit 1, and Figure 12 is a duct frame unit 100C having a flame spreader block. 13 is an explanatory view for explaining the flame cut-off state of the duct frame unit 100C having a flame spread cutoff port, and FIG. 14 is a state in which the duct pipe is installed through the wall W of the building. It is an explanatory diagram for explanation.

As shown in the accompanying Figures 1 to 14, the fiber refractory duct pipe unit 1 of the present invention is formed of iron or reinforcing material, and the front rim 110 of a hollow square shape, and the front rim ( 110) and the rear rim 120 of the same size and shape, and the front and rear rims 110, 120 to connect the front and rear rims 110, 120, respectively, connecting parts 111 ( 121) Four connecting bars 130 coupled to the inner side of the four ears and four connecting rods 140 coupled to the inner central point of the four connecting portions 111 and 121 of the front and rear frames 110 and 120 ) and a duct frame unit 100 configured as an integral body to maintain the skeleton of the duct; The outside of the semi-non-combustible insulation 310 made of any one of rectangular ceramic wool, glass wool, or silica gel of a predetermined thickness that is wrapped around and coupled to the outside of the duct frame unit 100 to form a duct pipe A fire-resistant fiber sheet 300 of a predetermined thickness formed by wrapping with any one of a fire-resistant material 320 of Hwacheon or a glass film; The duct frame unit 100 is formed with a length that can wrap the outer periphery of the fiber refractory sheet 300 surrounded and in contact with the outside of the region between the front and rear outward flange portions 112 and 122 of the duct frame unit 100, the coupling bolt (b) ) through the fibrous refractory sheet 300 and bolted to the front and rear rims 110 and 120 connection parts 111 and 121 of the duct frame unit 100, the fibrous refractory sheet 300 In the fiber-resistant duct pipe unit comprising; a fixing frame 400 for firmly coupling and fixing the to the outside of the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100, the In the middle region of the duct frame unit 100, it is formed in a cross shape made of a flame retardant or flame retardant material to form a nut hole n at each cross end, and a connecting bar 130 inside the duct frame unit 100 and The inner reinforcing bar 210 located in the center of the connecting bar 140, and a nut hole n at a point corresponding to each cross end of the inner reinforcing bar 210 is formed of an iron piece or a reinforcing material of a predetermined length. The connecting bar 130 at a position corresponding to the inner reinforcing bar 210 and the outer reinforcing bar 220 wound around the outside of the connecting bar 140 are nut formed on the outer reinforcing bar 220 by the coupling bolt (b). A support structure 200 that is bolted and fixed to each nut hole n formed at each cross end of the cross-shaped inner reinforcing bar 210 through the ball n to increase the supporting strength for wind pressure and air volume inside the duct pipe (200) characterized in that it is provided.
In addition, the duct frame unit 100 of the fiber refractory duct pipe unit 1 of the present invention for achieving the above object is a protrusion of the preceding duct frame unit 100 when the duct frame unit 100 is connected between the duct frame units 100. The connecting bar 130 and the connecting rod 140 are inserted and coupled to the inlet (not shown) of the trailing duct frame unit 100 to increase the bonding strength between the line and the trailing duct frame unit 100 (not shown). By inserting and coupling a predetermined width into the connecting portion 111 of the front rim 110, an inlet (not shown) is formed inside the connecting portion 111 of the front rim 110, and the rear rim 120 of It is characterized in that a protrusion (not shown) is formed outside the connection part 121 .

It will be described in more detail below.

First, the duct frame unit 100 is formed of an iron material or a reinforcing material, and as shown in Fig. 1 (c), the front frame 110 of a hollow square shape, and the front frame 110, such as In order to connect the rear rim 120 and the front and rear rims 110 and 120 of the same size and shape, each of the connection parts 111 and 121 of the front and rear rims 110 and 120 are four ears. Including four connecting bars 130 coupled to the inside and four connecting bars 140 coupled to the inner central point of the four connecting parts 111 and 121 of the front and rear frames 110 and 120, respectively. constituted as one.

That is, the duct frame unit 100 is spaced apart by a predetermined interval so that the front and rear rims 110 and 120 are respectively connected to each other so that the connecting parts 111 and 121 face each other, as shown in FIG. 1 ( c ). and then bolt or rivet the connection bar 130 to the inside of each of the connecting parts 111 and 121 of the front and rear rims 110 and 120, respectively, and the front and rear rims 110 The connecting rod 140 is bolted or riveted to the inner central point of each of the connecting portions 111 and 112 of the four sides of 120 to be integrally configured.

At this time, the coupling means is coupled by a coupling bolt (b) and a coupling nut (n, hereinafter, coupling nut, nut body, and nut ball are all denoted as "n" for convenience), but rivet coupling or welding coupling is also possible. Of course.

The length of the duct frame unit body 100 in this embodiment is formed to a length of 600 mm or more and 700 mm or less, and the length is small compared to the absolute length of the 1400 mm standard, which is a conventional duct length. The workability is very good.

When the length of the duct frame unit 100 is less than 600 mm, the number of duct frame unit units 100 required for connection construction up to a predetermined length at the duct installation site is excessively large, so the manufacturing cost is excessive and uneconomical, and the duct When the length of the frame unit 100 exceeds 700 mm, it is difficult to handle by a single worker, so there is a disadvantage in that workability is lowered during duct construction. The present inventor went through a long trial and error to the duct frame unit 100. When the length of the duct is 600mm or more and 700mm or less, it was found that it is a desirable length for one worker to install the duct without the help of an auxiliary worker.

In addition, the front rim 110 is formed as a hollow square rim in this embodiment. Of course, the present invention is not limited thereto, and it may be formed in any one shape of a rectangular frame, a circular frame, or a polygonal frame.

The front rim 110, as shown in Fig. 1 (a), the connecting portion 111 for connecting the rear rim 120, and the outward flange portion 112 for coupling the adjacent duct frame 100 are formed in a shape that is orthogonal to each other.

In the present embodiment, the connection part 111 was formed by cutting a hollow square tube made of an iron plate having a thickness of 2 mm to a width of 50 mm.

Of course, the connection part 111 can also be formed by welding both ends of the iron piece having a thickness of 2 mm and a width of 50 mm by bending it into a hollow square shape.

On the other hand, the outward flange portion 112 is formed by cutting out a 2mm thick iron plate into a 30mm wide hollow square, the shape and size of the inner diameter portion of the outward flange portion 112 is the outer surface of the connecting portion 111. It is formed in the same shape and size.

Therefore, the front rim 110 is, as shown in Fig. 1 (a), a hollow square outward flange portion of a predetermined width to be perpendicular to the outer surface of the one side open end of the hollow square connecting portion 111 having a predetermined width ( 112) is formed integrally by joining the inner diameter portions.

In addition, the rear rim 120 is formed in the same shape and size as the front rim 110 . Accordingly, the connection part 121 and the outward flange part 122 of the rear rim 120 are formed to have the same shape and the same size to correspond to the connection part 111 and the outward flange part 112 of the front rim 110, respectively. .

The connection parts 111 and 121 of the front and rear rims 110 and 120 in this embodiment have a thickness of 2 mm and a width of 50 mm, and the outward flange portions 112 of the front and rear rims 110 and 120 ) (122) is an example of a thickness of 2 mm and a width of 30 mm.

On the other hand, the connecting bar 130 is provided with four, each of the connecting portions 111 and 112 of the front and rear rims 110 and 120 are coupled and fixed inside the four ears, in this embodiment 2mm thick and a cross-section "L"-shaped angle 131 of a predetermined length with a width of 30 mm on one side was used. However, the present invention is not limited thereto, and it is of course also possible to form using other reinforcing materials.

In addition, the connecting rod 140 is provided with four, each of the connection parts 111 and 121 of the front and rear frames 110 and 120 are coupled and fixed to the inner central points of the four sides, respectively, in this embodiment A flat iron piece with a thickness of 2 mm and a width of 30 mm was used. However, the present invention is not limited thereto, and it is of course also possible to form using other reinforcing materials.

On the other hand, any one of the lower surface or one side of the duct frame unit 100 may be configured by combining the branch wire connection structure 150 as shown in FIG. 2 instead of the connecting rod 140 .

The accompanying Figure 2 is a view showing the coupling of the branch wire connection structure to one surface of the duct frame unit body 100 of the present invention.

The branch wire connection structure 150 refers to a connection structure for connecting a duct branch wire made of a bellows for sucking gas, dust, etc. from a crater provided on a dining table of a restaurant.

The branch wire connection structure 150 is, as shown in FIG. 2, a circular or prismatic connector 151 capable of coupling a connection part (not shown) of a duct branch wire from all sides using a fixing member 152. It refers to a thing fixed by bolting or riveting to the lower surface or one side of the duct frame unit 100 .

In addition, the duct frame unit 100 is, by coupling the connecting bar 130 and the connecting rod 140 to the inside of the connecting portion 111 of the front frame 110 by a predetermined width, the connection portion of the front frame 110 . (111) It is also possible to form an inlet (not shown) on the inside, and to form a protrusion (not shown) on the outside of the connection part 121 of the rear rim 120 .

This is, when connecting between the duct frame units 100, the protrusion (not shown) of the preceding duct frame unit 100 is inserted into the inlet (not shown) of the following duct frame unit 100, and then bolted or riveted. It is preferable to be able to increase the bonding strength between the line and the trailing duct frame unit 100 .

For reference, the duct frame unit 100 is, when the front and rear rims 110 and 120 are square rims (or rectangular rims) as described above, the front and rear rims 110 and 120 inside the four ears. A connection bar 130 having a cross-section "L"-shaped angle 131 of a predetermined length with a width of 30 mm and a thickness of 2 mm is used, but the front and rear frames 110 and 120 are polygonal or circular frames. A predetermined number of flat iron pieces (not shown) of a predetermined length with a width of 30 mm and a thickness of 2 mm are used inside the plate at predetermined intervals.

On the other hand, in the duct frame unit body 100, the wind pressure and wind volume received by the connecting bar 130 and the connecting rod 140 of the duct frame unit body 100 from the strong air flow flowing through the inside of the duct. In order to provide this, it is possible to prevent distortion of the duct pipe by coupling the support structure 200 to the central point of the connecting bar 130 and the connecting rod 140 of the duct frame unit 100 .

3 is an explanatory view of the inner reinforcement 210 coupled to the inner central portion of the duct frame unit 100, and FIG. 4 is an explanatory view of the inner reinforcement 210 from the outside of the inner reinforcement 210 of FIG. 3 by combining the external reinforcement 220 It is an explanatory view of the formed, duct frame unit body (100A) combined with the support structure.

The support structure 200 is composed of an inner reinforcing bar 210 and an outer reinforcing bar 220, as shown in FIGS. 3 and 4 .

The inner reinforcing bar 210 is formed in a cross shape made of a flame retardant or flame retardant material to form a nut hole n at each cross end, and a connecting bar 130 and a connecting bar 140 inside the duct frame unit 100 ) is located in the center of

In addition, the outer reinforcing bar 220 is formed of an iron piece or a reinforcing material of a predetermined length in which a nut hole (n) is formed at a point corresponding to each cross end of the inner reinforcing bar 210 to the inner reinforcing bar 210 . It is provided wrapped around the outside of the connecting bar 130 and the connecting rod 140 of the corresponding position.

The support structure 200, through the nut hole (n) formed in the outer reinforcing bar 220 by the coupling bolt (b), each of the nut holes (n) formed at each cross end of the cross-shaped inner reinforcing bar (210) By being bolted and fixed to the central part of the duct frame unit 100, as shown in FIG. 4, the duct frame unit 100A in which the support structure is combined is formed.

At this time, the duct frame unit body 100A combining the support structure adjusts the length of the connecting bar 130 and the connecting rod 140 according to the curvature and length of the curved portion when the duct installation position is a curved portion, as shown in FIG. As shown, a duct frame unit body (100B) combined with a support structure for installing a curved portion is formed.

In addition, at this time, in order to block the spread of fire by flame, smoke, gas, etc. flowing into the duct when a fire occurs in the building, the penetration part of the fire compartment divided into the wall W and the wall or layer and layer is shown in Figs. As shown in Fig. 14, by combining the duct frame unit 100C having a flame spread cutoff port, it is possible to quickly block the spread of fire through the duct pipe.

The duct frame unit body 100C having the flame spread cutoff member is configured in which the flame spread cutoff member 500 is integrally coupled to the inner central region of the connecting bar 130 and the connecting rod 140 of the duct frame unit 100. will be.

At each of the third and third points of the upper and lower sides of the duct frame unit 100C having the flame spread cutoff, the first upper side crossbar 230, the second upper side crosspiece 240 and the first The lower side crossbar 250 and the second lower side crosspiece 260 are welded to each other in the horizontal direction.

The flame spread cut-off port 500, the first phase side rail 230 and; a second lower side rail 260; Left and right ramps 510 and 510' made of a rectangular tube having a rectangular cross-section for welding both ends of the first upper side bar 230 and the second lower side bar 260; a hinge 520 coupled to the front surface of the first phase side crossbar 230; a rectangular flame blocking plate 530 having an upper side hinged to the front of the first upper side crossbar 230; It includes a; shape memory alloy iron wire 540 which is a hook for fixing the flame blocking plate 530 by lifting the lower side and hanging on the second upper side crossbar 240 .

The shape memory alloy iron wire 540 is a metal that remembers the shape when the shape was initially made even when deformation occurs and returns to its shape when the temperature reaches a certain temperature.

Therefore, by lifting the lower side of the flame blocking plate 530 hinged to the front side of the first phase side crosspiece 230, the upper side of the second phase side crosspiece 240 with a shape memory alloy iron wire 540 set at a predetermined shape recovery temperature. ), when the flame flowing into the duct pipe reaches a predetermined shape recovery temperature when a fire occurs, the shape memory alloy iron wire 540 immediately returns to its original shape and the flame blocking plate 530 loses its own weight. It will fall and close the inside of the duct pipe.

At this time, it is preferable that the hinge 520 is provided with a spring 522 on the hinge shaft 521 in order to promote the fall of the flame blocking plate 530 by its own weight.

In addition, at this time, both ends of the hinge shaft 521 protruding outside the duct pipe so as to easily identify the open state and the closed state of the flame blocking plate 530 of the flame diffusion barrier 500 from the outside It is also preferable to couple and fix the plate opening/closing cover (not shown).

5 is an explanatory view of the fibrous refractory sheet 300, and FIG. 6 is a duct frame unit 100A coupled with the support structure of FIG. 4 to the outside of the fibrous refractory sheet 300 and the fixing frame 400 ) is a view showing the fiber refractory duct pipe unit (1) of the present invention formed by fixing.

The fiber refractory material sheet 300 is, as shown in FIG. 5, the outside of the semi-non-combustible insulating material 310 made of any one of rectangular ceramic wool, glass wool, or silica gel having a predetermined thickness, non-woven silver foil, fire protection cloth or glass. It is formed by wrapping with any one of the refractory fibers 320 of the film.

The thickness of the fiber refractory sheet 300 is formed to a thickness of 35mm or more and 45mm or less. If the thickness of the ceramic wool sheet 300 is less than 35mm, the flame passed during the firefighting test was insufficient for the purpose of fire prevention, and when it exceeds 45mm, there was a problem in that it was not economical due to an increase in the production cost. In this embodiment, it was safe to use a fiber refractory material sheet 300 made of ceramic wool having a thickness of 40 mm.

The fiber refractory sheet 300 has the same width as the width of the region between the front and rear outward flanges 112 and 122 of the duct frame unit 100A that combines the support structure, and the duct frame unit unit that combines the support structure (100A) is formed with the same length as the outer circumference of the connecting bar 130 and the connecting rod 140.

The fiber refractory sheet 300 is, as shown in FIG. 6, the connecting bar 130 and the connecting rod 140 in the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100A that combines the support structure. ), it is surrounded and combined to form a duct pipe as an integral part.

The fibrous refractory material sheet 300 is bonded to the outside of the joint between the front end and the rear end so as to maintain airtightness with a flame retardant tape.

On the outside of the left and right ends of the fiber refractory sheet 300, as shown in FIG. 6, in contact with the front and rear outward flanges 112 and 122, a fixing frame 400 made of an iron piece of a predetermined width or a reinforcing material. This is combined to fix the fiber refractory sheet 300 to the outside of the duct frame unit 100A to which the support structure is coupled.

On the other hand, the fixing frame 400 is, as shown in FIG. 6, the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100A that combines the fibrous fire resistant sheet 300 with the support structure. It is for coupling and fixing to the outside of the duct frame unit (100A) having a thickness of 2mm and a width of 30mm or a reinforcing material, and the area between the front and rear outward flanges 112 and 122 of the duct frame unit body 100A that combines the support structure. It is formed with a length that can wrap the outer periphery of the fibrous fire resistant sheet 300 that is in contact with the outside.

As shown in FIG. 6, the fixing frame 400 penetrates the fiber refractory material sheet 300 through the nut hole n formed in the fixing frame 400 by a coupling bolt b to combine the support structure. By being bolted to the front and rear rims 110, 120 and connection parts 111 and 121 of the duct frame unit 100A, the fiber refractory material sheet 300 is combined with the support structure. The front of the duct frame unit 100A , It is firmly coupled and fixed to the outside of the area between the rear outward flange parts 112 and 122 .

That is, by wrapping and bonding the fiber refractory sheet 300 to the outside of the duct frame unit 100A that combines the support structure, the left and right ends of the fiber refractory sheet 300 are fixed with the fixing frame 400 in FIG. It is to form the fiber refractory material duct pipe unit (1) of the present invention as shown.

In the same way, after wrapping and bonding the fibrous refractory sheet 300 to the outside of the duct frame unit 100B that combines the support structure for installing the curved part, the left and right ends of the fibrous refractory sheet 300 are fixed with the fixing frame 400. After forming a fibrous refractory material duct pipe unit (1') for installing a curved part, and wrapping and bonding the fibrous refractory sheet 300 to the outside of the duct frame unit 100C having a flame diffusion blocker, the fibrous refractory sheet 300 By fixing the left and right ends of the frame 400 with the fixing frame 400, a fiber refractory material duct pipe unit (1”) having a flame spread cutoff port is formed.

According to the fiber refractory material duct pipe unit 1 of the present invention formed as described above, in the case of a duct made of a conventional zinc iron plate material, the blower (not shown) is installed at the end of the duct when the blower (not shown) starts to operate. ), when a negative pressure is temporarily formed in the duct pipe and the zinc iron plate forming the duct pipe is pulled inward and crushed, a very loud roar is generated, and even when the blower (not shown) is finished, the inside of the duct pipe continues Due to inertia, the flow of air rushes toward the end of the duct pipe where the blower (not shown) is installed, temporarily creating a strong positive pressure in the duct pipe, and the roaring noise generated when the crushed zinc iron plate is pushed out and unfolded is very loud. Although it was a factor in the occurrence of civil complaints due to noise, as shown in FIGS. 4 to 6 , the support structure 200 coupled to the central portion of the connecting bar 130 and the connecting rod 140 of the duct frame unit 100 . A fiber refractory sheet that is wrapped around and in contact with the outside of the connecting bar 130 and the connecting rod 140 in the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100A combining the coupling and the support structure. The fiber refractory material duct pipe unit 1 of the present invention formed by the combination of 300 can prevent the duct pipe from being crushed even when the blower (not shown) installed at the end of the duct starts operation or when the operation is finished, so that the generation of roaring noise Since there is no concern, the possibility of civil complaints caused by noise is eliminated.

Next, the accompanying Figure 7 is a view for explaining the assembly (D) composed of two and one set of the fiber refractory material duct pipe unit (1) of Figure 6, and shows only the frame of the assembly (D) for convenience of understanding.

As shown in the accompanying Figure 7, for easy construction at the construction site, it is very useful in construction to configure the combination (D) composed of two and one set of the fiber-resistant duct pipe unit (1).

By successively connecting the coupling body (D), it is possible to easily form a duct suitable for the length of the duct installation position.

8 is a view for explaining a state in which the fiber-resistant duct pipe unit (1) and its combination (D) are connected in succession to install a duct suitable for the length of the duct installation location, and for convenience of understanding, the fiber-resistant material Only the frame of the duct pipe unit (1) and its combination (D) is shown.

On the other hand, the attached figure 9 is a view for explaining the fibrous fire-resistance duct pipe unit 1' for installation in a curved part, and is a view showing only the frame for convenience of understanding, and FIG. 10 is a fiber-resistant fire-resisting duct pipe unit 1' for installation in a bent part (1') Two It is a diagram for explaining the assembly (D') composed of one set, and shows only the frame of the assembly (D') for convenience of understanding.

When the duct installation position is a curved portion, as shown in FIGS. 9 to 10, the length of the connecting bar 130 and the connecting rod 140 is adjusted according to the curvature and length of the curved portion to install the curved portion as shown in FIG. The fiber refractory material duct pipe unit (1') is constituted, and the combination (D') composed of two sets of the fiber fireproof material duct pipe unit (1') for installing the bent portion is formed, and the fiber fireproof material duct tube unit for the bent portion installation (1') is formed. ) and the coupling body (D') are connected in succession, so that it will be possible to easily install the duct in any duct installation environment, such as a curved part.

Next, a method for installing an insulating duct (2) using the fiber refractory duct pipe unit (1) of the present invention will be described in detail.

11 is a flow chart of a method (2) for installing an insulating duct using the fibrous fire resistant duct pipe unit (1) of the present invention.

Insulation duct installation method (2) using the fiber refractory material duct pipe unit (1) of the present invention, as shown in FIG. 11, the connecting bar 130 and the connecting rod ( 140) and the forming step (S1) of the duct frame unit body 100 to combine: the duct frame unit body 100 is built inside the inner reinforcement 210 of the support structure 200, outside the support structure 200 outside A duct frame unit body (100A) combining a support structure, which is configured by combining the reinforcing bar (220), forming step (S2-1) and; When the duct installation position is a curved part, the duct frame unit body 100B combining the support structure for installing the curved part is formed by adjusting the length of the connecting bar 130 and the connecting rod 140 according to the curvature and length of the curved part (S2-2) )Wow; In the inner central region of the connecting bar 130 and the connecting rod 140 of the duct frame unit 100, the flame diffusion barrier 500 is integrally coupled to the wall and the wall or floor of the building to block the spread of fire in the event of a fire. A duct frame unit body (100C) having a flame spread cutoff installed in a penetration portion of a fire compartment divided into layers (S2-3) forming step (S2-3); The outside of the semi-non-combustible insulating material 310 made of any one of rectangular ceramic wool, glass wool, or silica gel is wrapped with any one of non-woven silver foil, fire protection cloth, or glass film fiber fire resistant material 320 to form a fiber fire resistant sheet 300 A fiber refractory sheet forming step (S3) and; After wrapping and bonding the fiber refractory sheet 300 to the outside of the duct frame unit 100A combining the support structure, the left and right ends are fixed with a fixing frame 400 to form the fiber refractory duct pipe unit 1 of the present invention Fiber refractory duct unit forming step (S4) and; A combination (D) forming step (S5) of forming a combination (D) combining two of the fiber refractory material duct pipe units (1) as one set; The fiber refractory material duct pipe unit (1) and its combination (D) are connected to the duct installation position of the building, and when the duct installation position is a curved part, the fiber refractory material duct pipe unit (1') for installing a curved part is connected and installed, Insulation duct installation step (S6) of connecting and installing a fibrous fire-resistance duct pipe unit (1 ″) having a flame spread cut-off port in the penetration part of the fire compartment divided into walls and walls or floors and floors of the building (S6); It is made including; .

It will be described in more detail below.

1. Duct frame unit body 100 forming step (S1)

First, the connection part 111 of the duct frame unit body 100 is formed by cutting a hollow square tube made of a 2mm-thick iron material to a predetermined length, that is, a 50mm width.

In this case, the connection part 111 may be formed by welding an iron piece having a predetermined length having a thickness of 2 mm and a width of 50 mm in a square shape and welding both ends in contact with each other.

Next, the outward flange portion 112 is formed by cutting out an iron plate having a thickness of 2 mm into a hollow square having a predetermined width, that is, a width of 30 mm. At this time, the shape and size of the inner diameter of the outward flange portion 112 is the connection portion ( 111) It is formed in the same shape and size as the shape and size of the outer surface.

A plurality of front rims 110 are formed by joining the inner diameter portions of the outward flange portion 112 at a right angle along the outer surface of one end of the connection portion 111 . A plurality of rear rims 120 are formed in the same manner as above.

The front and rear rims 110 and 120 are spaced apart from each other by a predetermined distance so that the respective connecting portions 111 and 121 face each other, and the inner side of the front and rear rims 110 and 120 connecting portions 111 and 121 . The connecting bar 130 is bolted or riveted to the four ears, respectively, and the connecting rod 140 is bolted to the center of the inner, upper, lower, left and right surfaces of the front and rear rims 110, 120 and the connecting parts 111, 121, respectively. Combined or riveted to complete the configuration of the duct frame unit body (100).

At this time, it is also possible to combine the branch wire connection structure 150 instead of the connecting rod 140 on any one surface of the lower surface or one side of the duct frame unit body 100 .

2. Formation step (S2-1) of the duct frame unit body (100A) combined with the support structure

In the inner central portion of the connecting bar 130 and the connecting rod 140 of the duct frame unit body 100 configured as described above, a flame retardant material or a flame-retardant cross shape formed in a cross shape to form a nut hole n at each cross end portion The inner reinforcing bar 210 is erected, and the outer reinforcing bar 220 made of iron or reinforcing material is coupled to the outside of the position corresponding to the inner reinforcing bar 210 through the nut hole (n) formed in the outer reinforcing bar 220. By coupling and fixing with a coupling bolt (b) to a nut hole (n) formed at each cross end of the cross-shaped inner reinforcing bar (210), the duct frame unit body (100A) in which the support structure is coupled is formed.

3. Formation step (S2-2) of the duct frame unit body (100B) combining the support structure for installing the curved part

When the duct installation position is a curved part, the duct frame unit body 100B combining the support structure for installing the curved part is formed by adjusting the length of the connecting bar 130 and the connecting rod 140 according to the curvature and length of the curved part (S2-2) )to be.

4. Formation step (S2-3) of the duct frame unit body (100C) having a flame spread blocker

In order to quickly block the spread of fire through the duct pipe when a fire occurs, the flame spread breaker 500 is integrally combined with the connecting bar 130 of the duct frame unit 100 and the inner central area of the connecting rod 140. It is a forming step (S2-3) of the duct frame unit 100C having a flame diffusion barrier for coupling to the wall (W) and the wall of the building or the penetration part of the fire compartment divided into floors and floors.

5. Fiber refractory sheet forming step (S3)

The outside of the semi-non-flammable insulating material 310 made of any one of 40 mm thick ceramic wool, glass wool, or silica gel is wrapped with a non-woven fabric silver foil, fire-fighting cloth, or fiber-resistant material 320 of any one of glass film, and the support structure is The width of the front and rear outward flanges 112 and 122 of the combined duct frame unit 100A is the same as the width, and the connecting bar 130 and the connecting rod 140 of the duct frame unit 100A combined with the support structure A fiber refractory material sheet 300 having the same length as the length of the outer circumference is formed.

6. Fiber refractory material duct pipe unit (1) forming step (S4)

First, a fixing frame 400 made of an iron piece having a thickness of 2mm and a width of 30mm or a reinforcing material having a length that can wrap the outer circumference of the fiber refractory sheet 300 is formed.

Next, the fiber refractory material sheet 300 is wrapped around the outside of the duct frame unit 100A to which the support structure is combined, and the joint portion is adhered to keep airtightness with a flame retardant tape.

Next, by coupling the fixing frame 400 to the left and right ends of the fiber refractory sheet 300, the fiber refractory sheet 300 through the nut hole (n) formed in the fixing frame 400 by the coupling bolt (b). By bolting the front and rear rims 110, 120, and connection parts 111 and 121 of the duct frame unit 100A through which the support structure is combined, the duct that combines the support structure with the fiber refractory material sheet 300 By fixing to the outside of the frame unit 100A, as shown in FIG. 6, the formation of the fibrous fire-resistant duct pipe unit 1 of the present invention is completed. Since this process can be operated on the ground, the bonding process can be carried out very easily.

At the same time, the fibrous fire-resistance duct pipe unit (1') for installing the curved part is used for the installation position of the duct in the curved part, and the flame used in the penetration part of the fire compartment divided into the wall (W) and the wall or the layer and the layer of the building The formation of the fiber refractory material duct pipe unit (1”) having a diffusion barrier is completed.

7. Combined body (D) forming step (S5)

This is a step of forming a binder (D) by combining the two fibrous fireproofing duct pipe units (1) formed as described above as a pair.

The accompanying Figure 7 is a view for explaining the assembly (D) composed of two and one set of the fibrous fire-resisting duct pipe unit (1), and shows only the frame of the assembly (D) for convenience of understanding.

The rear outward flange portion 122 of the fiber refractory duct unit (1) formed as described above and the front outward flange portion 121 of the other fiber refractory duct tube unit (1) adjacent thereto are combined with a fastening bolt or rivet, in Figure 7 Forms a combination (D) of two and one set of fiber refractory duct pipe units (1) such as.

At the same time, it is also possible to form a combination (D') of two sets of fiber refractory duct pipe units (1') for installing a curved part to be used in a duct installation position of a curved part.

8. Insulation duct installation step (S6)

The fiber refractory material duct pipe unit (1) and its combination (D) formed in the above are connected to the duct installation position of the building, and when the duct installation position is a curved portion, the fibrous fireproof material duct tube unit (1 ') and its combination for installing a curved portion (D') is connected and installed, and the fiber refractory material duct unit (1”) equipped with a flame spreader is connected to the penetration part of the fire compartment divided into walls (W) and walls or floors and floors of the building. This is a step to complete the installation of the heat insulation duct using the fiber refractory material duct pipe unit (1) of the present invention.

According to the fiber refractory material duct pipe unit (1) of the present invention made as described above and the insulating duct installation method (2) using the same, it is easy to store and transport, has excellent constructability, and has excellent thermal insulation performance to prevent fire risk in advance. and no noise is generated at the start or end of the blower installed at the end, so the cause of civil complaints is eliminated and it is very economical in terms of production cost due to its low cost. A fiber refractory material duct pipe unit capable of preventing flame spread by blocking and a method for installing an insulating duct using the same are provided.

The present invention has been described in detail with respect to the preferred embodiment of the fibrous fire resistant duct pipe unit (1) and the insulating duct installation method (2) using the same, but the present invention is not limited thereto. It is possible to carry out various modifications within the scope of one drawing, and it will be apparent that this also falls within the scope of the present invention.

1 Fiber refractory duct pipe unit
Fiber refractory duct pipe unit for 1' curved installation
1” Fiber refractory duct pipe unit with flame diffusion barrier
2 Insulation duct installation method using fiber refractory duct pipe unit
100 duct frame unit
Duct frame unit combined with 100A support structure
100B Duct frame unit combined with support structure for installation of curved parts
Duct frame unit equipped with 100C flame diffusion barrier
110 Front frame 111 Connection part 112 Outward flange part 120 Rear edge 121 Connection part 122 Outward flange part 130 Connection bar 131 Cross-section "L"-shaped angle 140 Connection rod 150 Branch wire connection structure 151 Connection part 152 Fixture
200 Support structure 210 Inner reinforcing bar 220 Outer reinforcing bar 230 Defrost side grail 240 2nd upper side gable 250 1st lower side gable 260 2nd lower side gable
300 Fiber refractory sheet 310 Semi-non-combustible insulation 320 Fiber refractory material
400 fixed frame
500 Flame diffusion barrier 510 Inclined bar 520 Hinge 521 Hinge shaft 522 Spring 530 Flame barrier plate 540 Shape memory alloy iron wire
D Fiber refractory material duct pipe unit composed of two units
D' Combined body consisting of two units of fiber-repellent duct pipe for bending installation
b Coupling bolt n Coupling nut (nut body, nut hole)
S1 duct frame unit formation stage
S2-1 Duct frame unit formation step combining support structure
S2-2 Duct frame unit formation step combining the support structure for bending installation
S2-3 Formation step of duct frame unit with flame diffusion barrier
S3 Fiber refractory sheet forming step S4 Fiber refractory material duct pipe unit forming step S5 Combined body forming step S6 Insulation duct installation step W bulkhead

Claims (25)

It is formed of iron or reinforcing material, and a front frame 110 of a hollow square shape, a rear frame 120 having the same size and shape as the front frame 110, and the front and rear frames 110 ( 120), each of the connection parts 111 and 121 of the front and rear rims 110 and 120, four connecting bars 130 and the front and rear rims 110 and 120 coupled to the inside of the four ears ) of each of the connecting portions 111 and 121, including four connecting rods 140 coupled to the inner central point of the four sides, and the duct frame unit 100 for maintaining the skeleton of the duct; The outside of the semi-non-combustible insulation material 310 made of any one of rectangular ceramic wool, glass wool, or silica gel of a predetermined thickness that is wrapped around and coupled to the outside of the duct frame unit 100 to form a duct pipe A fire-resistant fiber sheet 300 of a predetermined thickness formed by wrapping with any one of a fire-resistant material 320 of Hwacheon or a glass film; The duct frame unit 100 is formed with a length that can wrap the outer periphery of the fiber refractory sheet 300 surrounded and in contact with the outside of the region between the front and rear outward flange portions 112 and 122 of the duct frame unit 100, the coupling bolt (b) ) through the fibrous refractory sheet 300 and bolted to the front and rear rims 110 and 120 connection parts 111 and 121 of the duct frame unit 100, the fibrous refractory sheet 300 In the fiber-resistant duct pipe unit comprising; a fixing frame 400 for firmly coupling and fixing the to the outside of the area between the front and rear outward flanges 112 and 122 of the duct frame unit 100, the In the middle region of the duct frame unit 100, it is formed in a cross shape made of a flame retardant or flame retardant material to form a nut hole n at each cross end, and a connecting bar 130 inside the duct frame unit 100 and The inner reinforcing bar 210 located in the center of the connecting bar 140, and a nut hole n at a point corresponding to each cross end of the inner reinforcing bar 210 is formed of an iron piece or a reinforcing material of a predetermined length. The connecting bar 130 at a position corresponding to the inner reinforcing bar 210 and the outer reinforcing bar 220 wound around the outside of the connecting bar 140 are nut formed on the outer reinforcing bar 220 by the coupling bolt (b). A support structure 200 that is bolted and fixed to each nut hole (n) formed at each cross end of the cross-shaped inner reinforcing bar 210 through the ball (n) to increase the supporting strength for wind pressure and volume inside the duct pipe Fiber refractory duct pipe unit, characterized in that it is provided. delete delete delete delete delete delete According to claim 1, wherein the duct frame unit 100, the protrusion (not shown) of the preceding duct frame unit 100 when connecting between the duct frame unit 100, the inlet of the following duct frame unit 100 ( (not shown), the connecting bar 130 and the connecting rod 140 are inserted into the connecting portion 111 of the front frame 110 to increase the bonding strength between the line and the trailing duct frame unit 100. By engaging the width of the lead-in, to form an inlet (not shown) inside the connection part 111 of the front rim 110, and to form a protrusion (not shown) to the outside of the connection part 121 of the rear rim 120 Fiber refractory duct pipe unit, characterized in that. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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