KR102027317B1 - Fire door for thermal barrier - Google Patents

Abstract

The present invention relates to a heat shield fire door, and more particularly, by forming at least one condensation prevention hole in the lower part of the fire door to act as a buffer between the interior and the interior of the fire door, thereby reducing the structural strength of the door or It is to prevent condensation without adding a separate configuration.
In particular, in the present invention to prevent condensation phenomenon, both sides of the indoor frame minimizes the temperature difference, and the inside of the outdoor frame minimizes the humidity, so that the indoor side using humidity and temperature characteristics without special structural changes, etc. Of course, the present invention relates to a heat shield fire door for preventing condensation from occurring inside and outside the fire door.
In addition, the present invention comprises a heat insulating material in the interior of the door, and by further comprising a heat insulating material with improved heat insulation performance along the edge of the door, to further improve the condensation prevention effect and at the same time to the fire door of the metal material by the temperature change according to the season Deformation can be prevented beforehand.
Therefore, it is possible to improve the reliability and competitiveness in the field of fire doors, especially in the field of fire door structure having a heat shielding function for preventing dew condensation, as well as in related fields.

Description

Fire door for thermal barrier

The present invention relates to a heat shield fire door, and more particularly, by forming at least one condensation preventing hole in the lower part of the fire door to act as a buffer between the interior and the interior of the fire door, thereby reducing the structural strength of the door or It is to prevent condensation without adding a separate configuration.

In particular, in the present invention to prevent condensation phenomenon, both sides of the indoor frame minimizes the temperature difference, and the inside of the outdoor frame minimizes the humidity, so that the indoor side using humidity and temperature characteristics without special structural changes, etc. Of course, the present invention relates to a heat shield fire door for preventing condensation from occurring inside and outside the fire door.

Condensation may occur on the inside or outside of the door in seasons with large indoor and outdoor temperature differences, such as summer or winter, and condensation may occur more frequently in winter.

In particular, in the case of the front door or the fire door is made of a metal material in most cases, because the inner panel and the outer panel of the metal material is directly connected to each other, the heat transfer between the inside and the outside is easy, condensation phenomenon This happens frequently.

This condensation is not limited to the dew condensation on the door, it can flow down and spread to the adjacent area, there are various problems such as hygiene problems such as mold generation, as well as causing corrosion of the door.

One of the technologies for preventing condensation, the Republic of Korea Patent Publication No. 10-1502562, the following prior art document 'door insulation frame' (hereinafter referred to as 'prior art 1'), the interior and exterior through the metal frame In order to prevent the heat exchange between the inner, the insulating bar is formed between the inner frame and the outer frame, the technology for blocking the heat exchange between the inner frame and the outer frame and to improve the thermal insulation effect.

In the case of the prior art 1, the structural strength of the door is inevitably lowered due to the material properties of the insulating bar connecting the inner frame and the outer frame, and it is fundamentally unreasonable to be applied to a fire door that must endure a high temperature and external force in the event of a fire. In the case of a general door, structural damage may occur on the connection part side of the insulation bar when used for a long time.

Another technology for preventing condensation, Korean Patent Publication No. 10-1746928, 'Fireproof Door Door Frame with Condensation Prevention Function' (hereinafter referred to as 'prior art 2') is provided through a gap between the door and the door frame. The technology is applied to block the inflow of outside air.

However, the prior art 2 can be heat exchange between the interior and exterior through the frame of the fire door, the surface temperature of the inner part of the frame is significantly lowered and dew is formed on the inner surface of the fire door, so the problem of the general door intact It is difficult to prevent condensation.

Republic of Korea Patent Publication No. 10-1502562 'Insulation Frame for Door' Republic of Korea Patent Publication No. 10-1746928 'fire door door frame with a condensation prevention function'

In order to solve the above problems, the present invention by forming at least one condensation prevention hole in the lower portion of the fire door to act as a buffer between the interior and the interior of the fire door, reducing the structural strength of the door or separate It is an object of the present invention to provide a thermal barrier door that can prevent condensation without adding a configuration.

In particular, in the present invention to prevent condensation phenomenon, both sides of the indoor frame minimizes the temperature difference, and the inside of the outdoor frame minimizes the humidity, so that the indoor side using humidity and temperature characteristics without special structural changes, etc. Of course, it is an object of the present invention to provide a thermal barrier door for preventing heat condensation from occurring inside and outside the fire door.

In addition, the present invention comprises a heat insulating material in the interior of the door, and by further comprising a heat insulating material with improved heat insulation performance along the edge of the door, to further improve the condensation prevention effect and at the same time to the fire door of the metal material by the temperature change according to the season An object of the present invention is to provide a heat shield fire door that can prevent deformation from occurring in advance.

In order to achieve the above object, a heat shield for a fire door according to the present invention, the frame forming the outer appearance of the fire door; And a heat insulating material configured in the inside of the frame, wherein at least one condensation preventing hole is formed in the lower portion of the frame.

In addition, the frame, at least one condensation preventing hole may be formed on the lower surface of the lower.

In addition, the frame, at least one condensation preventing hole may be formed on at least one side of the lower both sides.

In addition, the frame, at least one condensation preventing hole may be formed on the interior side of the lower.

In addition, the heat insulating material, the first heat insulating material configured in the interior of the frame; And a second heat insulating material having a relatively high heat insulating performance as compared with the first heat insulating material, and configured on an interior side of the lower part of the frame.

In addition, the heat insulating material may have a relatively higher heat insulating performance than the first heat insulating material, and may extend to the second heat insulating material, and an inner extension heat insulating material configured along an interior side edge of the inside of the frame.

The heat insulating material may have a relatively high heat insulating performance as compared to the first heat insulating material, and may include a third heat insulating material configured on an outdoor side of the inner lower portion of the frame.

In addition, the heat insulating material may have a relatively high heat insulating performance compared to the first heat insulating material, and may extend to the third heat insulating material, and an outer extension heat insulating material configured along the outer side edge of the inside of the frame.

In addition, the heat insulating material, the first heat insulating material configured in the interior of the frame; And a fourth heat insulating material having a relatively high heat insulating performance compared to the first heat insulating material, and extending from both bottom surfaces of the inside of the frame to both bottom surfaces thereof.

In addition, the heat insulating material may have a relatively high heat insulating performance compared to the first heat insulating material, and may extend to the fourth heat insulating material and extend along the side and the upper surface of the inside of the frame; may include.

By the above solution, the present invention by using the condensation prevention hole formed in the lower portion of the fire door, the interior of the fire door to play a buffer role between the outside and the interior, thereby reducing the structural strength of the door or a separate configuration There is an advantage that can prevent condensation without adding.

Thus, the present invention has the advantage that it is possible to easily produce a fire door having a heat shield function while minimizing the labor and cost increase, because it can prevent the condensation without a large change in the structure of the basic fire door.

In particular, in the present invention to prevent condensation phenomenon, both sides of the indoor frame to minimize the temperature difference and the inside of the outdoor frame to minimize the humidity to prevent the formation of dew naturally due to temperature drop, do not make a special structural change, etc. There is an advantage that the condensation does not occur in the interior side as well as the interior and outdoor side of the fire door.

In other words, the present invention uses the structural characteristics of each layer of the fire door and the humidity and temperature characteristics in the air, thereby preventing condensation from occurring even without a separate operation.

In addition, the present invention comprises a heat insulating material in the interior of the door, and by further comprising a heat insulating material with improved heat insulation performance along the edge of the door, to further improve the condensation prevention effect and at the same time to the fire door of the metal material by the temperature change according to the season There is an advantage that can prevent the deformation in advance.

Therefore, it is possible to improve the reliability and competitiveness in the field of fire doors, especially in the field of fire door structure having a heat shielding function for preventing dew condensation, as well as in related fields.

1 is a partially enlarged perspective view showing an embodiment of a heat shield fire door according to the present invention.
2 is a view for explaining the cause of the dew condensation.
3 is a view for explaining the condensation preventing function of FIG.
4 is a view showing embodiments of the condensation preventing hole shown in FIG.
5 to 9 is a configuration diagram showing embodiments of the heat insulating material shown in FIG.

An example of a heat shield for a heat shield according to the present invention can be applied in various ways, hereinafter with reference to the accompanying drawings will be described the most preferred embodiment.

1 is a partially enlarged perspective view showing an embodiment of a heat shield fire door according to the present invention.

Referring to FIG. 1, the thermal protection fire door A includes a frame 100 and a heat insulating material 200.

The frame 100 forms an outer shape of the heat shield fire door (A), and may be formed in various forms according to the type and characteristics of the heat shield fire door (A) and the needs of those skilled in the art, and in the present invention, the heat shield fire door (A) After the installation of the indoor ts frame 110 to look at the indoor side and the outdoor side frame 120 to look at the outdoor side will be described.

In addition, the indoor side frame 110 and the outdoor side frame 120 may be coupled stepwise as shown in Figure 1, according to the coupling structure of the thermal barrier (A) and the door frame (not shown). The outdoor side frame 120 may be coupled so as to protrude from at least one edge of the indoor side frame 110. Here, the indoor side frame 110 and the outdoor side frame 120 may be coupled by various methods according to the needs of those skilled in the art, such as bending, fitting, bolting, welding, etc., it is not limited thereto.

In addition, the frame 100 may be divided into an indoor side frame 110 and an outdoor side frame 120, as shown in Figure 1, the lower surface 111, both sides 112, forming the side portion of the frame 100 113 and the upper surface 114 may be formed to extend to the indoor side frame (110).

On the other hand, the moisture contained in the atmosphere is relatively heavier than the air, so it sinks in the lower portion, condensation occurs mainly in the lower portion of the fire door.

In the present invention, at least one condensation preventing hole 115 to 117 may be formed in the lower portion of the frame 100, and the function of the condensation preventing hole 115 to 117 will be described in detail below. .

Insulation material 200 is configured inside the frame of the frame 100, in consideration of the function of the fire door to block the movement of the flame in the event of a fire, as well as having a high fire and heat resistance characteristics, according to the present invention In order to improve the effect of the dew condensation function, it is preferable that the material is composed of a material having high moisture resistance and invasive resistance, which will be described in more detail below.

2 is a view for explaining the cause of the dew condensation.

Referring to FIG. 2, the condensation phenomenon is that when the air having a certain amount of water vapor S1 is cooled, when the temperature T1 is lowered (T2) past the dew point Ts, the amount of saturated water vapor at that temperature T2. This refers to a phenomenon in which water vapor (condensation amount, Δs) exceeding is condensed with dew.

This condensation phenomenon, as shown in (a) of Figure 2, it can be seen that a larger amount of water vapor condensation when the amount of water vapor contained in the atmosphere or the difference in air temperature before and after cooling is large.

As a result, in the case of a fire door made of metal, heat exchange between the outdoor side and the indoor side is easily performed through the metal frame having high thermal conductivity, and the temperature of the outside air affects the inside of the fire door. As the air is cooled, dew condensation occurs on the surface of the fire door.

On the other hand, in some fire doors, as shown in FIG.

However, in such a case, since the air (Ti, Si) from the indoor side of the high temperature and high humidity flows into the interior of the fire door, condensation may not occur on the interior surface of the fire door, but low temperature outdoor air (To) and high temperature and high humidity room Condensation occurs inside the fire door where the air (Ti, Si) of the side meets, and this causes a problem that the mold or corrosion of the fire door.

3 is a view for explaining the condensation preventing function of FIG.

Referring to Figure 3, the heat shield fire door (A) of the present invention is not in the form of moving the air as shown in (b) of Figure 2, the condensation prevention holes (115 to 117) shown in Figure 1 By the heat energy contained in the indoor air by the heat transfer to the heat insulating material 200 is characterized by inducing the temperature of the heat insulating material 200 to increase.

On the other hand, as described above, since the heat insulator 200 is made of a material having high moisture resistance and invasive resistance characteristics, the humidity inside the heat shielding fire door A is low because the moisture of the indoor side does not penetrate.

In other words, as shown in (a) of FIG. 3, the heat insulating material 200 configured inside the heat shield fire door A has a high temperature and high humidity air (Ti, Si) at the indoor side and a low temperature air (To) at the outdoor side. Maintain a moderate temperature dry state (Td, Sd) between.

As such, when the inside of the heat shield fire door A maintains a moderate temperature dry state, as shown in FIG. 3 (b), in the indoor side frame 110, the indoor side air is a medium temperature (Td) at a high temperature Ti. Even if it descends to), it does not pass through the dew point (Tsi) at the humidity (Si), so condensation may not occur.

In addition, in the outdoor side frame 120, a considerable temperature is lowered from the medium temperature (Td) to low temperature (To), but since the internal humidity (Sd) of the thermal insulation fire door (A) is low, similar to the indoor side frame (110). It does not pass through the dew point (Tso).

Therefore, the heat shield fire door A of the present invention can prevent the dew condensation from occurring not only on the interior surface but also inside the heat shield fire door A.

4 is a view showing embodiments of the condensation preventing hole shown in FIG.

The dew condensation prevention hole formed in the indoor side frame 110 constituting the thermal barrier (A) of the present invention, the first condensation prevention hole formed in the lower surface 111 as shown in (a) of FIG. 115, second condensation preventing holes 116 and third condensation preventing holes 117 formed on the first side 112 and the second side 113, respectively, as shown in FIG. 4B. As shown in (c) may include a fourth condensation preventing hole 118 formed on the interior side of the indoor side frame 110.

The condensation prevention holes 115 to 118 may be selected and combined at least one according to the purpose of use of the heat shielding fire door A, the functional characteristics, the coupling structure with the door frame, and the needs of those skilled in the art, and the frame 100. If the technical features that are formed in the lower portion of the, as well as the slit type shown in Figure 4 can be formed in various forms and various patterns, such as circular, oval, of course.

Hereinafter, a method of further improving the condensation prevention effect described above will be described by using the structural characteristics of the heat insulating material 200 configured inside the heat shielding fire door A. FIG.

5 to 9 is a configuration diagram showing embodiments of the heat insulating material shown in FIG.

Referring to FIG. 5, the heat insulating material 200 configured between the indoor side frame 110 and the outdoor side frame 120 shown in FIG. 1 may correspond to the overall shape of the frame 100. It may include a first heat insulating material 210 is configured and a second heat insulating material 220 is configured in the lower interior side of the first heat insulating material (210).

In particular, the second heat insulating material 220 has a relatively high heat insulating performance compared to the first heat insulating material 210, is configured on the interior side of the inner lower portion of the frame 100, the heat exchange or indoor side between the indoor side and the outdoor side By more effectively blocking the heat exchange between both sides of the frame 110, it is possible to more effectively prevent the occurrence of condensation on the interior surface of the heat shield fire door (A).

Referring to FIG. 6, the heat insulating material 200 configured between the indoor side frame 110 and the outdoor side frame 120 shown in FIG. 1 is a third heat insulating material configured on the lower outdoor side of the first heat insulating material 210. 230 may be included.

The third heat insulating material 230 is also configured to be the same as or similar to the second heat insulating material 220, and has a relatively high heat insulating performance compared to the first heat insulating material 201, and is configured on the outdoor side of the inner lower portion of the frame 100 In the same manner as the second heat insulator 220 described above, the heat exchange between the indoor side and the outdoor side or the heat exchange between both sides of the indoor side frame 110 is more effectively blocked, thereby providing the interior surface of the heat shield fire door A. Condensation can be prevented more efficiently.

Referring to FIG. 7, the heat insulating material 200 configured between the indoor side frame 110 and the outdoor side frame 120 shown in FIG. 1 is extended to the second heat insulating material 220 to form an inner portion of the frame 100. It may further include an outer extension insulation 231 extending along the inner side edge 221 and the third heat insulating member 230 formed along the interior side edges and configured along the edges of the outside side of the inside of the frame 100.

The inner extension insulating material 221 and the outer extension insulating material 231 are materials having a relatively high thermal insulation performance compared to the first heat insulating material 210, similar to the second heat insulating material 220 and the third heat insulating material 230 described above. It may be configured as, along the edge of the thermal barrier (A) to serve to prevent the edge of the frame 100 is deformed by the temperature change according to the seasonal change.

In FIG. 7, reference numeral 211 denotes a protrusion 211, and a second heat insulating material 220, a third heat insulating material 230, an inner extension heat insulating material 221, and an outer extension heat insulating material 231 on the second heat insulating material 210. ) Can be stably supported and combined.

Referring to FIG. 8, the heat insulating material 200 configured between the indoor side frame 110 and the outdoor side frame 120 shown in FIG. 1 has a relatively high heat insulating performance compared to the first heat insulating material 210. The lower surface of the inside of the frame 100 may include a fourth heat insulating material 240 which extends to the lower side of both sides.

In particular, the fourth heat insulator 240 is formed of an improved material compared to the first heat insulator resistance and moisture resistance and invasion resistance characteristics, in addition to the high heat insulation performance, condensation prevention holes formed in the indoor frame 110 (115 to 117) ), It is possible to prevent the moisture of the indoor side from penetrating into the interior of the heat shield fire door (A).

Through this, by keeping the internal humidity of the heat shield fire door (A) is low, it is possible to further improve the condensation prevention effect described in (b) of FIG.

At this time, when the condensation prevention hole 118 of the form shown in Figure 4 (c) is formed in the indoor side frame 110, the material of the second heat insulating material 220 shown in Figure 5 also improved the moisture resistance and invasion resistance characteristics Of course it can be used.

FIG. 9A illustrates a side extension insulating material 241 having a relatively high heat insulating performance as compared to the first heat insulating material 210, and extending to the fourth heat insulating material 240 to form a side surface and an upper surface of the inside of the frame 100. 9 (b) is along the edge of the first heat insulator 210, the lower heat insulating material 242, the first side having a relatively high heat insulation performance compared to the first heat insulator 210 The heat insulating material 243, the second side heat insulating material 244 and the upper heat insulating material 245 are shown.

As such, when additionally configuring heat insulating materials having relatively improved performance along the side surface of the first heat insulating material 210, while preventing moisture from penetrating into the interior of the heat shield fire door A, It is possible to prevent the edge of the frame 100 from being deformed by the temperature change according to the seasonal change.

Therefore, the heat shielding fire door A of the present invention does not significantly change the structure of the basic fire door, and by using the structural characteristics of each layer of the fire door and the humidity and temperature characteristics of the atmosphere, the condensation prevention effect is more effective. At the same time, it is possible to prevent deformation of metal fire door due to seasonal temperature change.

In the above, the fire door for thermal insulation by this invention was demonstrated. Such a technical configuration of the present invention will be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive.

A: Fire protection door
100: frame
110: indoor side frame
111: lower surface 112: first side
113: second side 114: upper surface
115: first condensation prevention hole 116: second condensation prevention hole
117: third condensation prevention hole 118: fourth condensation prevention hole
120: outdoor side frame
200: insulation
210: first insulation
220: second heat insulating material 221: inner extension insulation
230: third insulating material 231: outer extension insulation
240: fourth insulation 241: side extension insulation

Claims (10)

A frame forming an outer appearance of the fire door and having at least one condensation preventing hole formed at a lower portion thereof; And
Insulating material is configured in the interior of the frame, including;
The heat insulating material,
A first heat insulator configured inside the frame;
A second heat insulating material having a relatively high heat insulating performance compared to the first heat insulating material, and configured on an interior side of the lower part of the inner frame; And
A heat insulating door comprising: a third heat insulating material having a relatively high heat insulating performance compared to the first heat insulating material, the third heat insulating material configured on the outdoor side of the inner lower portion of the frame.
The method of claim 1,
The frame,
At least one condensation preventing hole is formed on the lower surface of the lower heat-resistant fire door.
The method of claim 1,
The frame,
At least one condensation preventing hole is formed on at least one side of both side surfaces of the lower thermal barrier door.
The method of claim 1,
The frame,
At least one condensation prevention hole is formed on the interior side of the lower heat-resistant fire door.
The method according to any one of claims 1 to 4,
The heat insulating material,
A thermal insulation fire door comprising: an inner extension insulating material having a relatively high heat insulating performance compared to the first heat insulating material, and extending to the second heat insulating material and configured along an interior side edge of the inside of the frame.
The method according to any one of claims 1 to 4,
The heat insulating material,
A heat insulation door comprising: an outer extension insulating material having a relatively high heat insulating performance compared to the first heat insulating material, and extending to the third heat insulating material and configured along an outer side edge of the inside of the frame.
A frame forming an outer appearance of the fire door and having at least one condensation preventing hole formed at a lower portion thereof; And
Insulating material is configured in the interior of the frame, including;
The heat insulating material,
A first heat insulator configured inside the frame; And
A heat insulating door comprising: a fourth heat insulating material having a relatively high heat insulating performance compared to the first heat insulating material, and extending from both bottom surfaces of the inside of the frame to both bottom sides thereof.
The method of claim 7, wherein
The heat insulating material,
The thermal insulation door for thermal insulation comprising a; has a relatively high heat insulating performance compared to the first heat insulating material, and extending to the fourth heat insulating material and configured along the side and the top surface of the inside of the frame. delete delete

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