KR101769209B1 - A dew condensation protecting device - Google Patents

Abstract

The present invention relates to a built-in long-term condensation prevention device, and more particularly, to a built-in condensation prevention device which prevents a condensation by generating a conveying air flow in a space between a built-in cabinet and a wall in a space where a built- The apparatus and method for preventing a temperature rise or a humidity of a space (310) formed between a vertical wall (120) and a built-in floor (200) in a built-in floor (200) spaced apart from a vertical wall A sensor 510 capable of being measured; And a gas flow forming unit (400) for gas communication between the space (310) and the outside of the built-in cabinet (200) according to the temperature or humidity of the space (310) measured by the sensor There is an effect of providing a comfortable indoor and cloth storage environment by preventing the occurrence of mold by suppressing the generation of condensation that may occur in the space between the built-in cabinet and the room.

Description

A built-in condensation protecting device

The present invention relates to a built-in long-term condensation prevention device, and more particularly, to a built-in condensation prevention device which prevents a condensation by generating a conveying air flow in a space between a built-in cabinet and a wall in a space where a built- Prevention device.

The built-in cabinet refers to a closet installed in a room and is installed close to one side wall.

Generally, it is excellent in terms of space utilization as a chest that is attached to a wall.

However, it is difficult to move the built-in cabinet once it is installed and there is a drawback that the space between the built cabinet and the wall is not opened unless the cabinet is completely separated.

This disadvantage results in condensation problems occurring in the space between the built-in wall and the built-in wall.

This is because there is a space between the built-in cabinet and the wall, and thus the temperature and humidity of the space between the wall and the space may correspond to the fungal habitat condition.

As a result, the condensation problem that can occur in the space between the built-in cabinet and the wall has a fatal problem that adversely affects the indoor environment as well as the interior of the closet by allowing the mold to grow better.

In order to solve such a problem, there has been a conventional ventilation fan installed in a wardrobe, which has a problem in that it can only remove moisture in the wardrobe by discharging the air inside the wardrobe to the outside, There has been a limitation in fundamentally failing to solve the problem of condensation occurring in the space between the rear part and the wall and the growing mold.

(Patent Document 1) KR2003-0094988 A

(Patent Document 2) KR2011-0121841 A

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems occurring in the prior art, and it is an object of the present invention to provide a built-in cabin system in which a space between a built-in cabinet and a vertical wall, The present invention aims to provide a built-in long-term condensation prevention device which removes condensation, as well as the habitat environment of the mold, by controlling the temperature and humidity of the inside of the slabs and the inside of the built-in cabin.

In order to solve the above-mentioned problems, the present invention provides a built-in cabinet 200 spaced apart from a vertical wall 120. The cabinet 200 includes a space 310 formed between the vertical wall 120 and the built- A sensor 510 capable of measuring the temperature or humidity of the sample; And a gas flow forming unit (400) for gas communication between the space (310) and the outside of the built-in cabinet (200) according to the temperature or humidity of the space (310) measured by the sensor Thereby providing a condensation prevention device.

The airflow forming unit 400 may be a built-in condensation preventing device located in a space 320 formed between the built-in cabinet 200 and the ceiling slab 110.

The airflow forming unit 400 may be a built-in condensation preventing device located above the rear edge of the built-in cabinet 200 in the spacing space 320.

Further, the airflow forming unit 400 includes a housing 410; A grill 420 formed in the housing 410 to open and close the space between the housing 410 and the space 310; A fan 430 installed in the housing 410 to transfer air to the grill 420; And a heater 440 for heating the air.

An auxiliary sensor 520 provided inside the built-in cabinet 200 for measuring the temperature or humidity inside the built-in cabinet 200 and transmitting an operation signal to the airflow forming unit 400; Condensation prevention device.

The sensor 510 may be a built-in condensation prevention device integrally formed with the airflow forming unit 400.

The airflow forming unit 400 may be a built-in condensation preventing device installed at the upper or lower end of the built-in field 200.

And an opening and closing part 600 installed between the front part of the built-in cabinet 200 and the ceiling slab 110 to open and close the interspace 310 and the flow of outside air, Lt; / RTI >

The bottom of the built-in cabinet 200 is spaced apart from the bottom slab 130 and the cabinet 200 is coupled to the support 250, It may be a built-in long-term condensation preventing device including an auxiliary airflow forming unit 450.

In addition, the sensors 510 and 520 and the airflow forming unit 400 include a built-in long-term condensation prevention device that is connected to a wired or wireless connection.

Also, the airflow forming unit 400 may be provided with a built-in condensation prevention device in which a desiccant unit including a desiccant for dehumidification is removably installed.

The present invention as described above has the following effects.

It is possible to prevent a mold from being generated by suppressing the generation of condensation that may occur in a space between the built-in cabinet and the room, thereby providing a pleasant indoor and cloth storage environment.

FIG. 1 is a side sectional view in which a built-in cabinet according to a preferred embodiment of the present invention is installed, and FIG. 2 is a graph of a temperature and a humidity shown through temperature and humidity conditions in an appropriate range in which mold growth conditions and molds can not grow.

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

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, the definitions of these terms should be described based on the contents throughout this specification.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side sectional view of a built-in cabinet according to a preferred embodiment of the present invention; FIG.

The walls and slabs of the rooms of the building 100 are divided into vertical walls 120 connecting the upper slabs (i.e., the ceiling slabs 110) and the floor slabs 130. FIG.

The built-in cabinet 200 has a front portion 240 facing the user and a rear portion 220 adjacent to the vertical wall 120 to be invisible to the user when the user uses the opening and closing door (not shown) And a lower end portion 230 adjacent to the bottom slab 130. The upper end portion 210 is adjacent to the bottom slab 110 and the lower end portion 230 is adjacent to the bottom slab 130. [

The built-in field 200 is spaced apart from the walls and slabs for its installation.

In other words, an interspace 310 is formed between the vertical wall 120 and the rear wall 220 of the built-in field 200 and the vertical wall 120.

In addition, a space 320 is formed between the top portion 210 and the ceiling slab 110, which form the upper end of the built-in cabinet 200.

In addition, the built-in field 200 may have a lower end portion 230 at a lower end thereof and at least one support portion 250 may be provided at a lower end portion 230 thereof.

The supporting portion 250 of the built-in cabinet 200 may be in close contact with the bottom slab 130 and a gap space 330 may be formed between the bottom end portion 230 and the bottom slab 130.

When the built-in cabinet 200 is installed in the room, a spacing space 320 is formed between the built-in cabinet 200 and the ceiling slab 110, and a space 320 is formed between the built- And a gap space 330 may be formed between the lower end portion 230 and the bottom slab 130. [

More specifically, a space 310 is formed between the rear surface of the built-in cabinet 200 and the vertical wall 120 so that a predetermined space is spaced apart from the rear surface 220. The rear surface 220 of the built- 310 may be provided to measure the temperature or humidity of the fluid.

Particularly, since the vertical wall 120 forms the outer wall of the building, a temperature difference between the outside of the building 100 and the indoor space may be significantly generated. As a result, the temperature and humidity of the interspace 310 may vary, May occur.

The auxiliary sensor 520 may also be installed inside the built-in cabinet 200 to measure the temperature and humidity of the internal space of the cabinet 200.

In other words, the auxiliary sensor 520 is installed in the built-in cabinet 200, and the airflow forming unit 400 operating signal is generated according to the temperature or humidity inside the built-in cabinet 200 measured by the auxiliary sensor 520 Unit 400 as shown in FIG.

The air flow forming unit 400 may be operated to open air in the interspace 310 through fine holes (not shown) Can be blown into the built-in field (200).

Conversely, the air inside the built-in field 200 may be sent to the interspace 310 through fine holes (not shown).

The air flow forming unit 400 may be provided for gas communication between the interspace 310 and the outside of the built-in field 200 according to the temperature or humidity of the interspace 310 measured from the sensor 510.

More specifically, the airflow forming unit 400 has a housing 410, and the housing 410 includes a grill 420.

The grill 420 is formed in the airflow forming unit 400 so as to communicate with the space 410 between the housing 410 and the housing 410 so as to open and close the housing 410. An angle adjusting means .

The airflow forming unit 400 may include a fan 430 installed in the airflow forming unit 400 to feed air through the grill 420.

It is also preferable that the airflow forming unit 400 is provided with a heater 440 for heating air to provide warm air.

On the other hand, the airflow forming unit 400 may be installed such that a dehumidifying agent unit (not shown) including a dehumidifying agent for dehumidifying can be detached.

More specifically, the dehumidifying agent unit (not shown) can be detachably provided to the housing 410 so that the dehumidifying agent unit can be stored or taken out.

The airflow forming unit 400 may be located in a spacing space 320 formed between the built-in cabinet 200 and the ceiling slabs 110.

The airflow forming unit 400 may be positioned above the rear portion 220 where the rear portion 220 of the built-in cabinet 200 meets the top portion 210 in the spacing space 320.

Meanwhile, an opening / closing part 600 may be provided between the front part 240 of the built-in cabinet 200 and the ceiling slab 110.

The opening and closing part 600 opens and closes the spacing space 320 so that air outside the built-in field 200 can communicate with the inside of the spacing space 320.

Meanwhile, the sensor 510 and the airflow forming unit 400 may be connected by a wire, but may also be wirelessly connected.

The sensor 510 is interlocked with the air flow forming unit 400 so as to grasp the temperature and humidity of the interspace 310 and operate the air flow forming unit 400.

It is also preferable that the sensor 510 is formed integrally with the airflow forming unit 400.

The auxiliary airflow forming unit 450 may be installed at the upper end 210 or the lower end 230 of the built-

The housing 410 is configured to support the support unit 250 by differentiating the shape of the housing 410 in the airflow forming unit 400.

In other words, the housing 410 of the auxiliary airflow forming unit 450 may be coupled to the support portion 250 of the built-in field 200 to provide a recess for supporting the built-in field 200 from the floor slab 130 It is.

The housing 410 of the auxiliary airflow forming unit 450 can circulate the air in the internal space of the interstice space 330 formed between the bottom slab 130 and the lower end 230 to the outside of the built-

The housing 410 of the auxiliary airflow forming unit 450 may be coupled to each of the supports 250 and may be any one of them.

Next, a preferred working example of the present invention will be described.

When the temperature or humidity of the space 310 measured by the sensor 510 corresponds to the habitat condition of the mold shown in FIG. 2, the airflow forming unit 400 applies an operation signal to the airflow forming unit 400, .

When the airflow forming unit 400 is operated, air in the interspace 310 can escape from the interspace 310 through fine holes (not shown) formed in the rear surface 220, And the humidity are out of the fungal growth condition interval of FIG. 2, thereby providing an environment in which mold can not be inhabited.

The airflow forming unit 400 can operate until the temperature or humidity of the interspace 310 measured from the sensor 510 falls within the appropriate range shown in FIG.

When the temperature and the humidity inside the built-in cabinet 200 measured by the auxiliary sensor 520 correspond to the mold growth conditions shown in FIG. 2, the airflow forming unit 400 is operated in the same manner to move the air in the built- It is possible to blow air into the spacing space 320 through the interspace 310 through a hole (not shown) and blow out the built-in field 200 by opening the opening and closing part 600, And humidity can maintain the appropriate range of environment in which the gompham of FIG. 2 can not grow.

Since the airflow forming unit 400 can be provided with the heater 440, the air blown through the airflow forming unit 400 is heated, and it is possible to effectively remove the moisture of the blown air.

Meanwhile, the grill 420 provided in the airflow forming unit 400 is operable to open and close the housing 410 and the outside, and the airflow direction can be adjusted through angle adjustment.

The housing 410 provided in the support part 250 is also operated by the sensor 510 to maintain the temperature or humidity in an appropriate range when the temperature or humidity of the interspace 310 falls within the mold growth condition shown in FIG. The air in the space 310 can be discharged to the outside of the built-in room 200 through the interstice space 330.

As described above, the ceiling slab 110 wall or the vertical wall 120 can be formed by the space formed between the built-in ceiling 200, the ceiling slab 110, the vertical wall 120 and the floor slab 130 installed in the indoor space. The air space forming unit 400 or the housing 410 is operated to suppress mold generation due to condensation which may be formed on the wall surface, the floor slab 130, or even the rear surface 220, The spacing space 320, and the interstice space 330 are not automatically formed so as not to form the fungal growth condition, thereby preventing the fungal growth.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

100: Building
110: ceiling slab
120: vertical wall
130: Floor slab
200: Built-in cabinet
310: Spacing space
320: Space between
330: Clearance space
400: airflow forming unit
410: Housing
420: Grill
430: Fan
440: Heater
450: auxiliary airflow forming unit
510: sensor
520: auxiliary sensor
600:

Claims (11)

In a built-in long-term condensation prevention device provided in a built-in cabinet (200) installed apart from a vertical wall (120)
The built-in long-term condensation prevention device includes:
A sensor 510 capable of measuring the temperature and humidity of the space 310 formed between the vertical wall 120 and the built-in field 200;
An auxiliary sensor 520 capable of measuring temperature and humidity inside the built-in field 200; And
And an air flow forming unit (400) for gas communication between the space (310) and the outside of the built - in cabinet (200)
The airflow forming unit 400 includes a heater 440 for heating air,
If the temperature and humidity inside the interspace 310 or the interior space 200 measured from the sensor 510 or the auxiliary sensor 520 correspond to a preset mold condition, the airflow forming unit 400 ) This works,
Built-in long-term condensation prevention device.
The method according to claim 1,
The airflow forming unit (400)
(320) formed between the built-in sheet (200) and the ceiling slab (110)
Built-in long-term condensation prevention device.
3. The method of claim 2,
The airflow forming unit (400)
(200), which is located above the rear edge of the built-in field (200) in the spacing space (320)
Built-in long-term condensation prevention device.
The method according to claim 1,
The airflow forming unit (400)
A housing 410;
A grill 420 formed in the housing 410 to open and close the space between the housing 410 and the space 310;
Further comprising a fan (430) installed in the housing (410) to transfer air to the grill (420)
Built-in long-term condensation prevention device.
delete The method according to claim 1,
The sensor 510 is formed integrally with the airflow forming unit 400,
Built-in long-term condensation prevention device.
The method according to claim 1,
The airflow forming unit (400)
[0030] In the present embodiment,
Built-in long-term condensation prevention device.
The method according to claim 1,
And an opening and closing part 600 installed between the front part 240 of the built-in cabinet 200 and the ceiling slab 110 to open and close the flow of the outside space and the outside space.
Built-in long-term condensation prevention device.
The method according to claim 1,
The built-in field (200) has a support portion (250) where the lower end portion (230) is supported on the ground,
A gap space 330 is formed in which the lower surface of the built-in cabinet 200 is separated from the floor slab 130 by the support part 250,
And an auxiliary airflow forming unit (450) for fluidly communicating the air in the interstitial space (330) with the outside of the built-
Built-in long-term condensation prevention device.
The method according to claim 1,
The sensor 510, the auxiliary sensor 520, and the airflow forming unit 400 are connected to each other through a wired or wireless connection,
Built-in long-term condensation prevention device.
5. The method of claim 4,
The airflow forming unit 400 is provided with a dehumidifying agent unit including a dehumidifying agent for dehumidifying,
Built-in long-term condensation prevention device.

Images