KR101021603B1 - Prefabricated panel improved fire resistance - Google Patents

Abstract

The present invention relates to a prefabricated panel having improved fire resistance performance, and more particularly, an upper panel and a lower panel which are spaced apart at regular intervals; An insulating material installed between the upper panel and the lower panel; And an adhesive layer formed between the upper panel and the insulation and between the lower panel and the insulation. The adhesive layer is formed by mixing the expandable mineral and the adhesive.

Prefabricated Panels, Sandwich Panels, Expandable Minerals, Vermiculite, Pearl Rock, Adhesives, Fire, Urethane Panels

Description

Prefabricated panel improved fire resistance

The present invention is to improve the existing prefabricated panel is vulnerable to fire, in order to minimize the human and physical damage caused by the degradation of the prefabricated panel itself when exposed to the fire to the prefabricated panel improved the fire resistance performance of the prefabricated panel itself. It is about.

Sandwich panels, which are widely used as building materials at home and abroad, that is, prefabricated panels combine heat insulating materials using adhesives between a pair of steel sheets, and are used in various buildings due to their excellent workability, heat insulation, and economic efficiency.

However, the prefabricated panel is vulnerable to fire in addition to the above advantages and needs a complementary measure.

In particular, Styrofoam, urethane foam, glass wool, mineral wool, etc. are used for the insulation of the prefabricated panel. Styrofoam or urethane foam is a flammable material, which may cause a great number of lives and property damages due to the rapid spread of toxic gases and fires in a fire. In addition, the urethane adhesive used for bonding the steel plate and the heat insulating material is also a combustible material is not free from the risk of fire.

Therefore, in order to secure the safety of fire by delaying the combustion of such combustible material, the building related law provides the following standard.

That is, the prefabricated panel for 1 hour fireproof structure needs to be more than 125mm thick, the density of the insulation material 74kg / ㎥ or more, the thickness of the upper and lower steel plate 0.5mm or more, and the rivets should be installed at intervals within 80mm when on-site construction. However, the prefabricated panel that satisfies these conditions is a unit panel of weight, which can increase air and construction costs due to poor productivity and workability.

In addition, in the case of using styrofoam as a heat insulating material, a process for improving the flame retardant performance through constant processing such as impregnating a flame retardant in styrofoam is additionally required. However, since the processed styrofoam due to the impregnation of the flame retardant is low in density, it causes bending and sagging of the prefabricated panel, thereby degrading productivity and transportability.

In addition, when the glass wool is used as a thermal insulation material, the glass wool board should be cut and used to have a thickness of 75 to 125 mm. Thus, there is a problem such as a waste of material and waste in the working environment due to dust and noise during the cutting process of the glass wool board. .

On the other hand, in the conventional prefabricated panel, in order to prevent damage to the prefabricated panel and to finish the treatment so that the fastening screws or pieces are not exposed to aesthetic appearance, there was a case where the U-shaped finish cap was coupled along the end of the prefabricated panel. . However, the U-shaped finish cap is difficult to dissipate heat due to the rise of the temperature of the prefabricated panel itself, and rather, the rise of the temperature of the panel itself tends to promote fire spread between adjacent building materials or spaces.

An object of the present invention created to solve the above problems is as follows.

First, by delaying the combustion of the heat insulating material and the adhesive constituting the prefabricated panel, to provide a prefabricated panel with improved fire resistance performance.

Second, to reduce the weight of the prefabricated panel to provide a prefabricated panel with improved fire resistance performance that can improve productivity and construction.

Third, to provide a prefabricated panel with improved fire resistance performance that can prevent the damage caused by the additional process because no processing or cutting process of the insulation.

Fourth, to provide a prefabricated panel with improved fire resistance performance is easy heat dissipation of the prefabricated panel itself.

In order to solve the above problems, the present invention provides an upper panel and a lower panel spaced apart from each other at regular intervals; An insulating material installed between the upper panel and the lower panel; And an adhesive layer formed between the upper panel and the insulation and between the lower panel and the insulation. Consisting of, the adhesive layer provides a prefabricated panel with improved fire resistance performance, characterized in that formed by mixing the expandable mineral and adhesive.

In addition, the present invention is located inside the insulation, the foam layer is formed by injecting an expandable mineral on the surface of the insulation; It may include, the upper surface and the side of the prefabricated panel, the L-shaped cap is coupled along the end of the prefabricated panel to surround the lower surface and the side; It can be configured to include.

Herein, the expandable minerals mixed into the adhesive or the expandable minerals injected into the insulation are foamed at the time of fire to form a constant heat insulating layer, thereby delaying the spread of the fire. In addition, the "L" shaped cap prevents the spread of fire due to the temperature rise of the panel itself by heat dissipation through the end of the prefabricated panel.

According to the present invention as described above is expected the following effects.

First, since the expandable minerals mixed into the adhesive or injected into the insulation are foamed in case of fire to form a heat insulation layer, the fire resistance performance can be improved by delaying the combustion of the prefabricated panel. Therefore, it is not necessary to increase the thickness or density of the thermal insulation material in order to delay fire spreading, thereby improving productivity and constructability of the prefabricated panel.

Secondly, in the case of using the present invention, since the processing or cutting process of the heat insulating material is unnecessary, it is possible to prevent the damage caused by the additional process.

Third, since the end cap is easy to heat dissipation is applied, it is possible to prevent the spread of fire due to the temperature rise of the prefabricated panel itself.

Fourth, the present invention is economical because it can be easily applied to the current prefabricated panel production system.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1 shows a cross-sectional view of the prefabricated panel 60 of the present invention, showing the prefabricated panel 60 before expansion of the expandable mineral 42.

The prefabricated panel 60 having improved fire resistance performance of the present invention has an upper panel 10 and a lower panel 20 positioned at a predetermined interval as shown in FIG. 1, and the upper panel 10 and the lower panel ( The insulating layer 30 is provided between the 20, and the adhesive layer 40 formed between the upper panel 10 and the insulating material 30 and between the lower panel 20 and the insulating material 30.

The upper panel 10 and the lower panel 20 are portions corresponding to the surface of the prefabricated panel 60, and a metal material such as steel sheet is mainly used. At this time, the thickness of the steel sheet is preferably within 2mm in view of the production cost and workability of the prefabricated panel 60.

And the heat insulating material 30 is to be installed between the upper panel 10 and the lower panel 20 for thermal insulation and insulation, styrofoam, urethane foam, glass wool, mineral wool and the like can be used. In particular, glass wool uses a glass surface, which is a first-class non-combustible material, as an insulating material, and has an advantage that there is almost no change in form or corrosion corresponding to an inorganic product. In general, the thickness of the heat insulating material 30 is configured in the range of 50 ~ 250mm in consideration of workability and thermal insulation.

On the other hand, the adhesive layer 40 is formed by mixing the expandable mineral 42 and the adhesive (44).

In this case, the expandable mineral 42 indicates an inorganic expandable gemstone such as vermiculite and pearlstone. Inorganic effervescent gemstones such as vermiculite and pearlite contain a large number of pores and contain a large amount of water. When the temperature reaches 100 to 700 ° C, the water contained in the expandable mineral 42 turns into steam and becomes bulky. It is foamed about 8 ~ 30 times. Vermiculite or pearlite in the foamed state is very light, low in thermal conductivity and low in fire, and has a fire resistance of 1400 ± 500 ° C.

In the present invention, the expandable mineral 42 gemstone as described above is processed into a powder having a particle size of 10 mm or less and mixed into the adhesive 44 to form an adhesive layer 40. Therefore, in the event of fire, the expandable minerals 42 contained in the adhesive layer 40 are foamed to form a non-combustible layer in the prefabricated panel 60, and as a result, safety of fire is prevented due to the combustion delay and the blocking of heat conduction of the adhesive layer 40. This is secured.

In addition, the adhesive 44 is used to attach the upper panel 10 or the lower panel 20 and the heat insulating material 30, and the one-component and two-component forms depending on whether the main body 46 and the curing agent 48 are separated. Divided into

In the case of the two-component type such as the urethane adhesive 44 and the epoxy adhesive 44, there is an advantage that the curing time can be adjusted according to the amount of the curing agent 48. In addition, other adhesives 44 capable of adhering inorganic materials may be used.

In particular, as an example of the adhesive 44, the main material 46 and the curing agent 48 are MDI (Diphenyl methane diisocyanate) and PPG (polypropylene glycol). The urethane adhesive 44 mixed with the above can be used.

At this time, the expandable mineral 42 and the adhesive 44 constituting the adhesive layer 40 are composed of the main panel 46, the expandable mineral 42, and the curing agent 48 separately or mixed with each other to form the upper panel 10 and It may be applied to one surface of the lower panel 20 facing.

Of course, even when the main body 46, the expandable mineral 42, and the curing agent 48 are separately applied, the adhesive layer 40 may be uniformly dispersed with each other so that the upper panel 10 and the lower panel 20 Combine the thermal insulation (30).

Meanwhile, the prefabricated panel 60 having improved fire resistance performance of the present invention is located inside the thermal insulation material 30 and is formed by injecting the expandable mineral 42 in the surface of the thermal insulation material 30. Characterized in that it comprises a.

The expandable mineral 42 injected into the foam layer 32, like the expandable mineral 42 incorporated into the adhesive layer 40, is foamed at the time of fire to form a non-combustible layer. In the present invention, the expandable mineral 42 is dropped from the upper portion, or penetrated from the surface of the insulating material 30 by using an injection mechanism and injected into the insulating material 30.

In addition, the present invention can be configured to include an L-shaped closing cap 50 is coupled along the end of the prefabricated panel 60 to surround the top and side, or bottom and side surfaces of the prefabricated panel 60. .

A-shaped closing cap 50 is coupled along the end of the prefabricated panel 60, by configuring a part of the end of the prefabricated panel 60 to be exposed to the outside air, it is possible to discharge the temperature of the prefabricated panel 60 itself in case of fire Thus, the heat is released to the outside of the prefabricated panel 60. At this time, the A-shaped closing cap 50 is bonded using an adhesive 44 or a piece or bolt.

2 shows a cross-sectional view of the prefabricated panel 60 of the present invention, showing the prefabricated panel 60 after expansion of the expandable mineral 42.

Prefabricated panel 60 of the present invention is the adhesive layer 40 formed between the upper panel 10 and the lower panel 20 and the heat insulating material 30 and the foam layer formed inside the heat insulating material 30 as shown in FIG. 32) foams as in FIG. 2 due to the temperature rise in a fire to form a constant non-combustible layer.

Therefore, in the case of using the present invention, since the time required for the expansion of the expandable mineral 42 to be foamed, and the fire transmission is delayed due to the thermal insulation layer formed due to the expansion of the expandable mineral 42, the fire resistance performance of the prefabricated panel 60 This is improved.

Finally, Figure 3 is a view showing an embodiment of the production method of the prefabricated panel 60 with improved fire resistance performance of the present invention.

The present invention (a) by applying or mixing each of the expandable mineral 42 and the adhesive 44 on the opposite surface of the upper panel 10 and the lower panel 20 of the upper panel 10 and the lower panel 20 Forming an adhesive layer 40 on one surface, and injecting the expandable mineral 42 on the surface of the insulating material 30 to form a foam layer 32 inside the insulating material 30; And (b) coupling the upper panel 10 and the lower panel 20 to the upper and lower surfaces of the thermal insulation material 30; It includes a method of producing a prefabricated panel 60, characterized in that the fire resistance performance is improved.

That is, the present invention, as can be seen in Figure 3, while the insulation layer 30 having a foam layer 32 formed therein is moved by a conveyor belt, the upper panel 10 and the lower panel 20, respectively While moving by the roller is combined with the heat insulating material 30 by the adhesive layer (40).

At this time, the main material 46, the expandable mineral 42, the curing agent 48 can be added in a manner that falls from the top through the pipe, respectively, and their input amount is adjusted by the size and discharge rate of the discharge device.

In addition, the main body 46, the expandable mineral 42 and the curing agent 48 are evenly distributed on one surface of the upper panel 10 or the lower panel 20 to a thickness of 5 mm or less, 3 mm or less and 5 mm or less, respectively. The amount of the expandable mineral 42 injected into one surface of the 10 or the lower panel 20 is preferably maintained at 2 kg / m 2 or less, respectively.

Of course, after the step (b), the step of combining the A-shaped finishing cap 50 along the end of the prefabricated panel 60 to surround the top and side, or bottom and side of the prefabricated panel 60 is Can be added.

In the embodiment of Figure 3, the main body 46, the expandable minerals 42 and the curing agent 48, respectively, are separately coupled to the steel sheet, the order of their input is not limited separately, it is also possible to mix and put at the same time.

While the invention has been described in connection with the preferred embodiments as mentioned above, various modifications and variations are possible without departing from the spirit of the invention. Therefore, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

1 and 2 show cross-sectional views of the prefabricated panels of the present invention, which show prefabricated panels before and after expansion of the expandable minerals, respectively.

Figure 3 shows a method of producing a prefabricated panel improved fire resistance performance of the present invention.

<Description of Major Symbols in Drawing>

10: top panel

20: lower panel

30: insulation

32: foam layer

40: adhesive layer

42: expansive mineral

44: adhesive

46: Subject

48: curing agent

50: L-shaped cap

60: prefabricated panel

Claims (5)

An upper panel 10 and a lower panel 20 spaced apart from each other by a predetermined interval; An insulating material 30 installed between the upper panel 10 and the lower panel 20; And, An adhesive layer 40 formed between the upper panel 10 and the heat insulating material 30 and between the lower panel 20 and the heat insulating material 30; To form a prefabricated panel 60, The adhesive layer 40 is formed by mixing the expandable mineral 42 and the adhesive 44, A-shaped closing cap 50 is coupled along the end of the prefabricated panel 60 to surround the top and side, or the bottom and side of the prefabricated panel 60; Prefabricated panel improved fire resistance performance comprising a. In claim 1, A foam layer (32) formed in the thermal insulation material (30) and formed by injecting an expandable mineral (42) on the surface of the thermal insulation material (30); Prefabricated panel improved fire resistance performance comprising a. The method of claim 1 or 2, The thermal insulation material 30 is a prefabricated panel improved fire resistance performance, characterized in that any one of styrofoam, urethane foam, glass wool, mineral wool. In claim 2, The expandable mineral 42 is a prefabricated panel with improved fire resistance performance, characterized in that the inorganic expandable gemstone. delete

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