CN212925511U - Multifunctional storage system for forced dehumidification after forced termination - Google Patents

Abstract

The utility model provides a force multi-functional storage system of dehumidification after forcing to end, include: a storage chamber (100); a machine room (200) operating in a specific mode; a storage unit (410) that receives and stores information on the specific mode when the specific mode ends; and a control part (430) controlling to operate the machine room (200) in a specific mode, wherein the storage part (410) is operative to store information about the specific mode at the end of the specific mode and transmit the information about the specific mode stored in the storage part (410) to the control part (430) when the multi-function storage system is normally operated after being forcibly ended, and the control part (430) controls to operate the machine room (200) to forcibly dehumidify the storage room (100) when it is determined that the operation is forcibly ended in any one of the preset modes using the information about the specific mode.

Description

Multifunctional storage system for forced dehumidification after forced termination

Technical Field

The present invention relates to a multifunctional housing system that performs forced dehumidification after forced termination, and more particularly, to a multifunctional housing system that stores information related to a mode being performed in a memory so that forced dehumidification is performed based on the information stored in the memory when the multifunctional housing system is forcibly terminated.

Background

Recently, with the deterioration of the concentration of fine dust, attention has been increasingly paid not only to the air quality of an indoor space but also to the treatment and management of clothes, shoes, quilts, and the like to which various contaminants floating outdoors and indoors may adhere. Accordingly, devices for removing contaminants and managing clothes, shoes, quilts, etc. are being developed, and there is an increasing trend toward devices having various functions associated therewith.

Generally, an apparatus for managing laundry is configured to clean laundry by removing dust, humidifying, dehumidifying, and finishing.

In this regard, as with other electronic devices, the device for managing laundry is also in use, and a situation may occur in which the device suddenly ends operation after the humidification mode is started due to a power outage or a user's misoperation. The above-mentioned case belongs to the end operation against the user's intention, in which case if there is no additional process such as dehumidification after the end operation, the inside of the receiving chamber will be put in a state where the moisture is not removed regardless, so that there may occur a problem of cloth damage of the laundry, a problem of odor generation caused by the residual moisture, and a serious hygienic problem such as a problem of bacteria propagation, but also in the case where the operation is forcibly ended due to the user's selection.

Korean granted patent No. 10-0672490 discloses a prior art regarding a device capable of managing laundry. However, the above-mentioned prior art discloses only a mode for managing laundry by ordinarily controlling the mode of the storage room. Therefore, it is difficult to expect a process for a case where the operation of the apparatus is suddenly ended or the apparatus is out of order due to a power failure or the like, that is, a problem that the residual moisture in the storage chamber cannot be removed when the operation is forcibly ended.

Therefore, in recent years, a technique capable of removing residual moisture remaining in the storage chamber after humidification is performed in the storage chamber has been required.

(patent document 1) Korean patent laid-open No. 10-0672490

SUMMERY OF THE UTILITY MODEL

Technical problem

The present invention is proposed to solve the above problems.

Particularly, the utility model aims at providing a multi-functional storage system that forces dehumidification after the completion is as follows: when the multifunctional storage system for cleaning clothes is forcibly ended due to forced power failure or misoperation of a user, residual moisture in the storage chamber for storing the clothes can be removed, so that the clothes stored in the storage chamber can be restored to a dry state, and the problems of bacterial propagation and odor generation in the storage chamber can be prevented.

In addition, the utility model aims at providing a multi-functional storage system that forces dehumidification after the completion is as follows: by forcibly dehumidifying in a specific manner according to the humidification progress state and the dehumidification progress state of the storage chamber, the clothes stored in the storage chamber can be optimally and forcibly dehumidified, and the power consumption can be minimized.

Technical scheme

In order to solve the above problem, the utility model provides a multi-functional storage system who forces dehumidification after forcing to end, include: a housing chamber 100; a machine room 200 operating in a specific mode; a storage part 410 which receives and stores information on a specific mode when the specific mode is ended; and a control part 430 controlling to operate the machine room 200 in a specific mode, wherein the storage part 410 is operative to store information about the specific mode at the end of the specific mode and transmit the information about the specific mode stored in the storage part 410 to the control part 430 when the multi-function storage system is normally operated after being forcibly ended, and the control part 430 controls to forcibly dehumidify the storage room 100 to operate the machine room 200 and forcibly dehumidify the storage room 100 when it is determined that the operation is forcibly ended in any one of preset modes using the information about the specific mode.

Further, it is preferable that the control part 430 is operated to determine a humidification mode (M) to supply humidified air to the receiving chamber 100 if it is determined according to the specific mode that it is forcibly ended in the operation in any one of the preset modes when it is determined using the information on the specific mode_Wet) Or a dehumidification mode (M) for dehumidifying the storage chamber 100_{Dry matter}) When the operation is forcibly terminated, the storage chamber 100 is forcibly dehumidified.

Further, it is preferable that the forcible dehumidification of the receiving chamber 100 by the control part 430 is performed by the machine chamber 200 for a preset time period for the receiving chamber 100.

Further, preferably, the control part 430 determines that the multifunctional storage system is in the humidification mode (M)_Wet) When the operation is forcibly finished, according to the humidification mode (M)_Wet) Controls a forced dehumidification period of the receiving chamber 100, and determines that the multifunctional receiving system is in the dehumidification mode (M)_{Dry matter}) When the operation is forced to be finished, according to the information about the dehumidification mode (M)_{Dry matter}) The information of the remaining time period of (b) controls the forced dehumidification time period of the receiving chamber 100.

Further, it is preferable that, in the case where information on a specific mode is stored in the storage part 410 at the end of the specific mode, information on the humidification mode (M) is stored_Wet) And information on the operated time period of the dehumidification mode (M)_{Dry matter}) Is transmitted from the control part 430 in real time and stored in the storage part 410, and is related to the humidification mode (M) when the information on the specific mode stored in the storage part 410 is transmitted to the control part 430 when the multifunctional storage system is normally operated after being forcibly ended_Wet) And information on the operated time period of the dehumidification mode (M)_{Dry matter}) Is transmitted from the storage section 410 to the control section 430.

Further, it is preferable that the humidification mode (M) is set in the control portion 430 with reference to the operated time period_Wet) The storage unit 410 is divided into a 1 st section to an Nth section, where N is a natural number of 1 or more, and when information on a specific mode is stored in the storage unit 410 at the end of the specific mode, when a K-th section, which is a section between the 1 st section and the Nth section, ends and enters a K + 1-th section, information on the end of the K-th section is stored in the storage unit 410, and when the multi-function storage system is being usedThe information on the specific mode stored in the storage part 410 during normal operation after forced termination is transmitted to the control part 430, the information on the end of the K-th section is transmitted from the storage part 410 to the control part 430, and the multifunctional storage system is determined to be in the humidification mode (M) when it is determined that the multifunctional storage system is forcibly terminated to perform control to forcibly dehumidify the storage chamber 100 during operation in any one of preset modes using the information on the specific mode_Wet) The forced dehumidification period of the machine room 200 at the forced end of the operation is determined by the humidification progress period which is the sum of the 1 st to K th sections.

Further, it is preferable that the dehumidification mode (M) is set in the control part 430 with reference to the operated time period_{Dry matter}) A 1 st section to an M th section, where M is a natural number of 1 or more, when information on a specific mode is stored in the storage part 410 at the end of the specific mode, when an L-th section, which is a section between the 1 st section and the M-th section, ends and enters an L +1 th section, the information on the end of the L-th section is stored in the storage part 410 from the control part 430, when the information on the specific mode stored in the storage part 410 in a normal operation of the multi-function storage system after being forcibly ended is transmitted to the control part 430, the information on the end of the L-th section is transmitted from the storage part 410 to the control part 430, and when it is determined that the forced end is forcibly ended in any one of the preset modes using the information on the specific mode to perform control to forcibly dehumidify the storage chamber 100, upon determining that the multifunctional storage system is in the dehumidification mode (M)_{Dry matter}) The forced dehumidifying time period of the machine room 200 at the forced end of the operation is determined by the dehumidifying remaining time period which is the sum of the 1 st section to the L th section.

Further, preferably, the specific mode further includes: preprocessing mode (M)_{Preparation of}) A discharge unit for discharging air into the storage chamber 100; and a post-processing mode (M)_{Rear end}) And supplies air to the storage chamber 100, wherein the control part 430 manages the storage chamber 100In the laundry management process of (a), the machine room 200 is operated to sequentially perform the pre-treatment mode (M)_{Preparation of}) The humidification mode (M)_Wet) The dehumidification mode (M)_{Dry matter}) And the post-processing mode (M)_{Rear end})。

Further, it is preferable that the case where the multi-function housing system is forcibly ended includes: a condition of interruption of power supply from a power source; and a case where the multi-function housing system is forcibly terminated regardless of the specific mode.

Further, it is preferable that the storage part 410 includes an electrically erasable programmable read only memory (EEP-ROM).

Furthermore, the utility model provides a multi-functional storage system, include: a housing chamber 100; a machine room 200 operating to form the receiving room 100 in a specific pattern; a storage part 410 which receives and stores information on the mode of the receiving chamber 100 when the mode of the receiving chamber 100 is ended; and a control part 430 controlling the operation of the machine room 200 in a specific mode, wherein, if the humidification mode (M) for supplying the humidified air to the receiving room 100 is determined according to the specific mode when the multifunctional receiving system is normally operated after being forcibly ended_Wet) Or a dehumidification mode (M) for dehumidifying the storage chamber 100_{Dry matter}) When the operation is forcibly terminated, the control unit 430 operates the machine room 200 to forcibly dehumidify the storage room 100.

Further, preferably, the machine room 200 includes: a dehumidifying part 260 dehumidifying the circulating air flowing through the receiving chamber 100; a circulation air inlet 141 and a circulation air outlet 142 which communicate the housing chamber 100 and the machine chamber 200; a circulation filter unit 229 that supplies moisture to the circulation air supplied to the housing chamber 100 through the circulation air inlet 141; and a fan unit 230 circulating air in a direction, wherein the humidification mode (M)_Wet) And the dehumidification mode (M)_{Dry matter}) In the humidifying mode (M) in a state where the machine room 200 is isolated from the outside air_Wet) The natural humidification air generated by the circulation filter unit 229Air is supplied to the receiving chamber 100 through the fan unit 230 and circulated, in the dehumidification mode (M)_{Dry matter}) Then, the air dehumidified by the dehumidifying part 260 is supplied to the receiving chamber 100 by the fan unit 230 and circulated while in the humidifying mode (M)_Wet) Or the dehumidification mode (M)_{Dry matter}) When the operation is forcibly terminated, the dehumidifying part 260 and the fan unit 230 are operated to forcibly dehumidify the receiving chamber 100.

Further, it is preferable that the pre-treatment mode (M) of supplying air to the receiving chamber 100 is performed_{Preparation of}) And a post-processing mode (M)_{Rear end}) In a state where the machine room 200 is isolated from the external air, only the fan unit 230 is operated to supply air to the receiving room 100.

Advantageous effects

According to the present invention, when the specific mode of the storage chamber is ended, the information on the end of the specific mode is stored in the storage part, and when the multifunctional storage system is normally operated, the residual moisture inside the storage chamber can be removed by forcibly dehumidifying the storage chamber using the information on the specific mode stored in the storage part, so that the dry state inside the storage chamber can be maintained even if the multifunctional storage system is forcibly ended. Therefore, even in the case where the user does not recognize that the multi-function storage system is forcibly ended, it is possible to prevent a problem that the laundry or the like stored in the multi-function storage system is damaged due to the residual moisture.

In addition, when the storage chamber is forcedly dehumidified, excessive forced dehumidification of the storage chamber can be prevented by considering the state of progress of the humidification mode and the dehumidification mode immediately before the forced termination of the multifunctional storage system, and therefore, the fabric of clothes and the like can be protected and excessive power consumption can be prevented.

Drawings

Fig. 1 is a schematic view of a multifunctional storage system according to an embodiment of the present invention, showing a state when in a humidifying mode (M)_Wet) The working state of the machine room arrangement and the air circulation during operation.

FIG. 2 is a schematic view showingThe utility model discloses a with dehumidification mode (M)_{Dry matter}) Schematic diagram of the working state and air circulation of the machine room configuration when operating and performing forced dehumidification.

FIG. 3 is a diagram showing the present invention in a preprocessing mode (M)_{Preparation of}) And a post-processing mode (M)_{Rear end}) Schematic representation of the working state and air circulation of the machine room arrangement in operation.

Fig. 4 is a flowchart for explaining a multifunctional storage system for performing forced dehumidification after the end of forcing according to an embodiment of the present invention.

Fig. 5 is a schematic diagram for explaining a first embodiment of the present invention.

Fig. 6 is a schematic diagram for explaining a second embodiment of the present invention.

Fig. 7 is a schematic diagram for explaining a third embodiment of the present invention.

FIG. 8A is a view showing a mode (M) in which humidification is performed in the third embodiment of FIG. 7_Wet) And a conceptual diagram of a storage procedure of the storage unit after the forced termination of each section at the time of operation.

FIG. 8B is a view showing a dehumidification mode (M) in the third embodiment of FIG. 7_{Dry matter}) And a conceptual diagram of a storage procedure of the storage unit after the forced termination of each section at the time of operation.

Description of the reference numerals

100: storage chamber

141: circulating air inlet

142: circulating air outlet

200: machine room

210: air suction inlet

219: cleaning filter unit

220: first flow path

229: circulating filter unit

230: fan unit

240: second flow path

241: first channel switching member

242: second flow path switching member

250: air vent

260: dehumidification part

270: water supply tank

280: condensate water tank

300: recirculation module

410: storage unit

430: a control unit.

Detailed Description

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. Hereinafter, the "laundry management course" refers to a predetermined course for cleaning laundry within the receiving chamber, but it is previously pointed out that the receiving chamber 100 receives and cleans all items requiring regular cleaning, such as bed clothes and dolls, in addition to the laundry. In addition, the "forced dehumidification" according to an embodiment of the present invention will be described below based on the case of the laundry management process, but it may be applied to all processes of implementing a humidifying operation or a dehumidifying operation of a receiving chamber.

1. Structural description of multifunctional storage system

Referring to fig. 1 to 3, the multifunctional storage system according to the present invention includes a storage room 100, a machine room 200, a recycling module 300, a storage part 410, and a control part 430.

The receiving chamber 100 is a space for receiving laundry and the like and removing pollutants or malodorous substances. For this reason, the natural humidified air may be introduced and circulated as the circulating air after the interior of the receiving chamber 100 is raised to the high temperature. Inside the receiving chamber 100, a circulation filter attachment portion (not shown), a circulation air inlet, and a circulation air outlet are provided on a lower surface. The circulation filter attachment portion is an opening provided to enable easy attachment and detachment of the circulation filter unit 229 located in the machine room 200 to repair or replace the circulation filter unit 229.

The circulation air inlet 141 and the circulation air outlet 142 are openings through which the circulation air inside the housing chamber 100 flows in and out of the machine chamber 200, respectively. The circulation air inlet 141 communicates with the fan unit 230 and is formed to discharge air from the machine room 200 toward the receiving room 100, and the circulation air outlet 142 is formed to circulate air from the receiving room 100 toward the machine room 200. In addition, a portion of the receiving chamber 100 communicating with the circulation air inlet 141 is formed to be inclined in an upper direction such that the air flowing in from the circulation air inlet 141 is discharged into the receiving chamber 100 with a predetermined angle upward from a bottom surface of the inside of the receiving chamber 100. Therefore, a contact area with the laundry or the like received in the receiving chamber 100 is larger than that of the circulation air discharged from the circulation air inlet 141 in the vertical direction, and the cleaning efficiency can be improved.

The machine room 200 is a space that performs the following functions: the air is circulated by introducing air from the receiving chamber 100 and filtering it in the "laundry management process" and then flowing out natural humidified air as circulating air. The machine room 200 includes a suction port 210, a first flow path 220, a fan unit 230, a second flow path 240, an exhaust port 250, a dehumidifying part 260, a water supply tank 270, and a condensate tank 280.

The suction port 210 is a portion for sucking external air into the machine room 200. The exhaust port 250 is a portion that receives filtered outside air from the second flow path 240 and discharges it to the outside. And may be turned on or off depending on the selection. A cleaning filter unit attaching part (not shown) may be located at the suction port 210 so that the cleaning filter unit 219 can be positioned. The cleaning filter unit 219 plays a role of filtering the sucked external air in an "air cleaning process" as another process of the multifunctional storing system, and may include a pre-filter, a HEPA filter, etc., but is not limited thereto.

The first flow path 220 communicates with the air inlet 210, the second flow path 240, and the fan unit 230. The circulation filter unit 229 is located inside the first flow path 220. The circulation filter unit 229 may function to filter the circulation air. The circulation filter unit 229 may include a humidification filter to which water is supplied in the course of passing the circulation air to form natural humidification air when the water stored in the water supply tank 270 is supplied thereto. The user may open a door (not shown) and access a recirculation filter disassembly (not shown) to remove or install the recirculation filter unit 229.

By the operation of the fan unit 230, the air inside the receiving chamber 100 flows into the second flow path 240 through the circulating air outlet 142, flows into the first flow path 220 again, and faces the fan unit 230. In this process, the air passes through the humidifying filter of the circulation filter unit 229 to become natural humidified air. The natural humidified air is again supplied to the storage chamber 100 through the circulating air inlet 141 through the second flow path 240. As this process is repeated, the circulation air is continuously circulated between the receiving chamber 100 and the machine chamber 200. The circulating air includes the pollutants or the malodor substances in the receiving chamber 100, but they are not discharged to the outside, thereby providing a comfortable environment for the user.

The second flow path 240 receives filtered outside air or circulated air from the fan unit 230. The second flow path 240 selectively communicates with any one of the housing chamber 100 and the exhaust port 250, and includes a first flow path switching member 241 and a second flow path switching member 242 for this control. The first flow path switching member 241 and the second flow path switching member 242 operate in pair to change the flow path. In an embodiment, the first and second flow path switching members 241 and 242 may be members that rotate around an axis, but any mechanism for selectively changing the flow path may be employed.

The dehumidifying part 260 performs a function of dehumidifying the circulating air flowing through the receiving chamber 100. The dehumidifying part 260 may be, for example, a heat pump, but is not limited thereto. Heat may be generated during the dehumidification by the dehumidifying part 260, which is not discarded and may be used for laundry management. For example, the housing chamber 100 is heated to about 50 to 70 degrees celsius by heat generated during dehumidification in the dehumidification unit 260, and then the room-temperature circulating air flowing in is received from the second flow path 240 through the circulating air inlet 141, so that contaminants such as laundry and malodorous substances can be removed. For another example, as described above, heat generated during dehumidification by the dehumidification part 260 is supplied to the humidification filters of the circulation filter unit 229 or to the pipes connected to the water supply tank 270 and the humidification filters, so that natural humidified air serving as circulation air can be heated. Of course, the above-described temperatures are examples, and the present invention is not limited thereto, and various changes may be made. In addition, only any one of the dehumidification portion 260 and the circulation filter unit 229 (i.e., the humidification filter) may be selectively operated so as not to interfere with each other.

The water supply tank 270 stores water that needs to be supplied to the humidification filters provided in the circulation filter unit 229. To this end, the circulation filter unit 229 is connected to a pipe. The condensed water tank 280 collects and stores condensed water generated in the receiving chamber 100, or collects and stores condensed water generated in a process in which saturated humid air generated in the receiving chamber 100 flows into the first flow path 220, the second flow path 240, or the like of the machine room 200 and is condensed. For this purpose, the condensate tank 280 is connected to the receiving chamber 100 and/or the first flow path 220 and/or the second flow path 220 by a pipe. In order to fill water or discard the filled condensed water, it is preferable that the water supply tank 270 and the condensed water tank 280 of the user can be easily accessed.

The machine room 200 may be located in any direction with reference to the receiving room 100, but is preferably located below the receiving room 100. This is because the condensed water or the saturated humidified air condensed in the receiving chamber 100 may be introduced into the machine room 200 by its own weight and discharged to the outside through the condensed water tank 280.

The recirculation module 300 assists in the circulation of the circulating air. Since the recirculation module 300 recirculates the circulating air at the upper side of the receiving chamber 100, convection is more smoothly performed in the entire receiving chamber 100. In addition, by operating independently of the operation of the machine room 200, it is also possible to operate for removing contaminants such as laundry stored in the storage room 100. Fig. 1 to 3 are illustrated based on the state in which the recirculation module 300 is provided, but the recirculation module 300 may not be provided, and even if the recirculation module 300 is provided, the recirculation module 300 may be configured not to operate when the fan unit 230 operates.

The storage part 410 is a space for storing information about the multi-function storage system. Regarding the storage section 410 of the present invention, "the first embodiment" is an embodiment for storing information on a specific mode of the multifunctional storage system. The "second embodiment" is to store information on the humidification mode (M) in real time for the multi-function storage system_Wet) Time elapsed of and dehumidification mode (M)_{Dry matter}) When there is a surplus ofLong examples of information. The "third embodiment" is a humidification mode (M) of the multifunctional housing system_Wet) Or a dehumidification mode (M)_{Dry matter}) An embodiment in which the division into subdivided sections and then the information on the end of a specific section are repeatedly rewritten in the storage section 410. The storage unit 410 may include an EEP-ROM (electrically erasable programmable read only memory), but is not limited thereto as long as it can store data. The EEP-ROM can write and delete information by the control section 430. The EEP-ROM may be configured as a nonvolatile memory in which information stored therein can be maintained without being erased even if power is turned off and stopped.

When the multi-function housing system is forcibly ended, the control part 430 loads the stored information from the storage part 410 of the multi-function housing system. After loading the information, it is determined whether it is a preset mode, and if it is the preset mode, forced dehumidification is commanded to the machine room 200. The device used in the control part 430 may include a microcomputer (MICOM), but is not limited thereto as long as the device can be used for operation and control. The microcomputer may be configured in the form of an extremely small computer equipped with an arithmetic processing section and a storage device.

Further, the storage section 410 may cooperate with the control section 430 to store various programs or data and the like. The program stored in the memory can be executed by the control section 430. Although the storage section 410 and the control section 430 are described in a separate configuration in this specification, this means functional separation rather than physical separation. The storage section 410 and the control section 430 may be integrally formed according to a system and an apparatus to be implemented.

2. Mode description and forced end operation method of multifunctional storage system

The machine room 200 may perform a pre-treatment mode (M) as a mode of the laundry management course_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) Post-processing mode (M)_{Rear end}) And the like. Hereinafter, the laundry management course is roughly classified into a pre-treatment mode (M)_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) Post-processing mode (M)_{Rear end}) But other modes related to laundry cleaning may be added. In addition, for the operation of the laundry management process, the machine room 200 may be operated to sequentially perform the pre-treatment mode (M)_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) And a post-processing mode (M)_{Rear end}) However, the preprocessing mode (M) may be omitted according to the selection of the user_{Preparation of}) And a post-processing mode (M)_{Rear end}) A part or all of them.

In addition, the "forcible termination" described below is classified into internal factors such as a failure of the multi-function storage system and external factors such as an operation error of the user and a forcible power-off, which means that all the cases where the user does not intend to forcibly terminate the operation of the operation are included. Further, it is a concept including all cases where the execution is forcibly ended due to the user's forcible ending intention.

_Wet1) Description of the humidifying mode (M)

Referring to fig. 1, the humidification mode (M) will be described_Wet) The lower machine room 200 configuration.

In the humidification mode (M)_Wet) In this case, the air sucked by the fan unit 230 is formed into natural humidified air while passing through the circulation filter unit 229. The circulation air inlet 141 and the circulation air outlet 142 are opened to circulate the natural humidified air into the receiving chamber 100. Here, the circulation filter unit 229 is provided with a humidification filter, and water is supplied from the water supply tank 270 to the humidification filter of the circulation filter unit 229, and the water stored in the water supply tank 270 is forcibly supplied by a supply pump (not shown).

Humidification mode (M)_Wet) A humid environment is created within the receiving chamber 100 by circulating natural humidified air into the receiving chamber 100. Therefore, the laundry stored in the storage chamber 100 can be humidified. Air particles contained in the naturally humidified air are combined with pollutant particles and malodor substances particles attached to the laundry, and in a dehumidification mode (M) described below_{Dry matter}) During the process of dehumidifying laundry in operation, pollutant particles and malodor material particles are removed from the laundry together.

Further, in fig. 1, the fan unit 230 is described as a suction fan, but the fan unit 230 may be a discharge fan, in which case the arrangement configured inside the machine room 200 may be rearranged to be suitable for the discharge fan.

_{Dry matter}2) When the dehumidification mode (M) is running

Referring to fig. 2, in the dehumidification mode (M) will be described_{Dry matter}) The lower machine room 200 is configured to operate. The following dehumidification mode (M)_{Dry matter}) The operation of the equipment room 200 disposed below is the same as the operation of the equipment room 200 at the time of forced dehumidification after the end of the forcing of the multifunctional storage system of the present invention.

In a dehumidification mode (M)_{Dry matter}) The dehumidifying part 260 inside the machine room 200 operates to dehumidify the circulation air flowing through the receiving room 100. In order to dehumidify the receiving chamber 100, the fan unit 230 may be operated to circulate the dry air, and the circulation air inlet 141 and the circulation air outlet 142 are opened. The condensed water generated at this time is stored in the condensed water tank 280. By performing a dehumidification mode (M)_{Dry matter}) The pollutant particles and the malodor substances particles on the laundry may be removed from the laundry.

In a dehumidification mode (M)_{Dry matter}) The operation of the lower machine room 200 configuration is the same as that of the machine room 200 at the time of forced dehumidification, but in order to dehumidify the receiving room 100 in a short time, the output of the dehumidifying part 260 may be designed to be in a specific dehumidification mode (M)_{Dry matter}) The lower is larger and the output of the fan unit 230 can also be designed to be larger, thereby increasing the air circulation speed. In addition, a dehumidification mode (M)_{Dry matter}) May be formed to be different from the time period of the forced dehumidification, and the designer may appropriately adjust the time period of the forced dehumidification within a range not to damage the fabric of the laundry stored in the storage chamber 100.

3) _{Preparation of Rear end}Run-time of pre-processing mode (M) and post-processing mode (M)

The preceding processing mode (M) will be described with reference to FIG. 3_{Preparation of}) And a post-processing mode (M)_{Rear end}) The lower machine room 200 is configured to operate.

Pretreatment dieFormula (M)_{Preparation of}) Is a starting step of the laundry management process, and functions to discharge air to primarily remove large dust or contaminants having relatively large particles attached to cloth and the like. Preprocessing mode (M)_{Preparation of}) Also referred to as "air shower mode", refers to a process of strongly spraying air. Before the contaminants and the like adhered to the laundry inside the receiving chamber 100 are completely removed, the contaminants are previously brushed off to improve the cleaning efficiency of the laundry. In a preprocessing mode (M)_{Preparation of}) In this case, the circulation filter unit 229 and the dehumidifying part 260 are not operated, but are configured to operate only the fan unit 230.

Post-processing mode (M)_{Rear end}) Is the last step of the clothes management process and has the following functions: by supplying air through the fan unit 230, it is possible to remove foreign substances, which may possibly remain in the laundry, again while rebuilding the inside of the receiving chamber 100. Preprocessing mode (M)_{Preparation of}) And a post-processing mode (M)_{Rear end}) The operation of the lower machine room 200 configuration is the same, but the output of the fan unit 230 may be controlled differently. For example, in a preprocessing mode (M)_{Preparation of}) The output of the lower fan unit 230 may be formed to be more than the post-processing mode (M)_{Rear end}) The output of the lower fan unit 230 is relatively greater.

Further, in the present specification, in the preprocessing mode (M)_{Preparation of}) And a post-processing mode (M)_{Rear end}) In a humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) However, the humidification mode (M) is described_Wet) And a dehumidification mode (M)_{Dry matter}) May be repeatedly performed a plurality of times, and the user may adjust the humidification mode (M) according to the type of laundry or the type of cloth stored in the storage chamber 100_Wet) And a dehumidification mode (M)_{Dry matter}) The number of executions of (c).

In addition, in the preprocessing mode (M)_{Preparation of}) And a post-processing mode (M)_{Rear end}) In (2), the housing chamber 100 and the machine chamber 200 are both communicated with each other, and preferably, are isolated from the outside air. Specifically, this is because: when executing the preprocessing mode (M)_{Preparation of}) In the meantime, if the machine room 200 is not isolated from the external air, the foreign particles inside the receiving chamber 100 may be discharged to the multi-function receiving chamberThe exterior of the storage system, thereby reducing the air quality of the space in which the multi-functional storage system is located. Post-processing mode (M)_{Rear end}) In order to prevent the influence on the humidity and temperature of the space where the multifunctional storing system is located, it is preferable that the machine room 200 is operated in a state of being isolated from the external air.

3. Description of forced dehumidification execution at forced termination of multi-function storage system

Fig. 4 is a flowchart illustrating a multifunctional storage system for performing forced dehumidification after the end of forcing according to an embodiment of the present invention. According to an embodiment of the present invention, the multifunctional storage system for performing forced dehumidification after the forced termination performs forced dehumidification after the forced termination through steps S110 to S150.

Step S110 is a step of storing information on the specific mode in the storage section 410 when the specific mode ends. Here, the specific mode includes the above-mentioned preprocessing mode (M)_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) And a post-processing mode (M)_{Rear end}). For example, when in preprocessing mode (M)_{Preparation of}) Ends and enters humidification mode (M)_Wet) When the preprocessing mode (M) is selected, the control unit 430 will control the preprocessing mode_{Preparation of}) The information of the end is transmitted to the storage unit 410 and stored in the storage unit 410.

Step S120 is a step in which the multi-function storage system is forcibly ended. As described above, this includes all cases where the multi-function storage system is forcibly ended, regardless of the intention of the user.

Step S130 is a step of transmitting information on the specific mode stored in the storage part 410 to the control part 430 in a normal operation after the multi-function storage system is forcibly ended. The storage section 410 stores information about the preprocessing mode (M)_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) And a post-processing mode (M)_{Rear end}) In normal operation, the control section 430 loads the stored information on the specific mode from the storage section 410 as the nonvolatile memory.

Step S140 is a step of performing control to forcibly dehumidify the storage chamber 100 when the control unit 430 determines that the operation in any one of the predetermined modes is forcibly ended using the information on the specific mode. Here, the preset mode may be set to the humidification mode (M) as follows_Wet) And a dehumidification mode (M)_{Dry matter}) And determining that the multifunctional storage system is in a humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) And when the operation is forcibly finished, performing forced dehumidification. More specifically, in the humidification mode (M)_Wet) When the operation is forcibly terminated, the residual moisture is retained in the current storage chamber 100, and forced dehumidification is required, and the dehumidification mode (M) is performed_{Dry matter}) When the operation is forced to be ended, the dehumidification mode (M) is not performed for a sufficient time_{Dry matter}) Therefore, residual moisture may remain inside the storage chamber 100, and therefore, forced dehumidification is required to remove the residual moisture.

Step S150 is a step of operating the machine room 200 by the control unit 430 to forcibly dehumidify the storage room 100, and the redundant description thereof is omitted as described above.

Hereinafter, an embodiment of a multifunctional storage system for performing forced dehumidification after the end of forcing will be described with reference to fig. 5 to 8B. The present invention describes a way of controlling the forced dehumidification of the receiving room 100 through three embodiments. The "first embodiment" is a manner of performing forced dehumidification using information of a mode performed at the end of the forcing (see fig. 5). The "second embodiment" is to use the mode (M) regarding the humidification_Wet) Has been executed for a long time or a dehumidification mode (M)_{Dry matter}) The remaining time period of time, to perform the forced dehumidification (see fig. 6). The "third embodiment" is a humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) Is subdivided into a plurality of sections, and when each section ends, the manner of performing forced dehumidification using information on the end section (see fig. 7).

In the first to third embodiments of the present invention, the humidification mode (M) is determined_Wet) Or a dehumidification mode (M)_{Dry matter}) Operation ofIn the case of performing forced dehumidification when the humidification is forcibly terminated, the case will be described as an example, but the humidification mode (M) is not used_Wet) Or a dehumidification mode (M)_{Dry matter}) The forced dehumidification may be performed in the same principle when the operation is forcibly ended in the other preset mode.

1) First embodiment (manner of performing forced dehumidification for a predetermined period of time)

The "first embodiment" is described with reference to fig. 5.

When the specific mode of the multi-function housing system is ended, information on the ended specific mode is stored in the storage part 410. For the storage of the storage part 410, the control part 430 and the storage part 410 are configured to transmit and receive an electric signal, and preferably, transmit information on a specific pattern ended in a protocol manner to the storage part 410. As described above, the information on the terminated specific pattern is rewritten in the storage section 410. In this case, since the storage section 410 is configured as a nonvolatile memory, even when the power supply of the multifunction accommodating system is cut off, the storage section 410 can maintain a state in which the latest rewriting information is stored.

After the multi-function housing system is forcibly ended, when normally operating again, the control part 430 loads the information stored in the storage part 410. Then, the control part 430 determines that the multifunctional storage system is in the humidification mode (M) using the information on the specific mode_Wet) Or in dehumidification mode (M)_{Dry matter}) The run is forced to end.

Sequential execution of preprocessing mode (M) with a multi-functional storage system_{Preparation of}) Humidification mode (M)_Wet) And a dehumidification mode (M)_{Dry matter}) And a post-processing mode (M)_{Rear end}) For reference, the multifunctional storage system is in a humidifying mode (M)_Wet) When the operation is forcibly terminated, the preprocessing mode (M) is stored in the storage unit 410_{Preparation of}) Status of the information of end. In addition, the multifunctional storage system is in a dehumidification mode (M)_{Dry matter}) When the operation is forcibly terminated, the storage unit 410 stores the information about the humidification mode (M)_Wet) Status of the information of end.

The information on the specific mode loaded from the storage section 410 at the control section 430 is about the preprocessing mode (M)_{Preparation of}) In the case of the information of the end, it is considered that the humidification mode (M) is used_Wet) The operation is forcibly terminated, and the information on the specific mode loaded from the storage part 410 at the control part 430 is about the humidification mode (M)_Wet) In the case of the information of the end, it is considered that the dehumidification mode (M) is used_{Dry matter}) The run is forced to end. In this way, the control section 430 performs a calculation process for making this determination, and when the loaded information on the specific mode is about the preprocessing mode (M)_{Preparation of}) Or a humidification mode (M)_Wet) When the information is completed, a forced dehumidification command is indicated to the machine room 200.

The forced dehumidification period is a preset period and may be preferably designed to perform 20 minutes, and power consumption of the multifunctional storage system may be minimized by preventing excessive dehumidification of the receiving chamber 100.

In addition, the preset time period may be set to a specific time period, but may be changed according to circumstances. For example, since the humidity of the space is different according to seasons, it may be changed according to seasons. The preset time can be prolonged when the humidity is high in summer, and the preset time can be shortened when the humidity is dry in winter. To this end, the control part 430 may be configured to transmit and receive wireless information on weather to receive external weather information.

2) Second embodiment (forced dehumidification based on the length of time of execution)

The "second embodiment" is described with reference to fig. 6.

The information on the executed time length and the information on the remaining time length of the mode of the multi-function storage system are configured to be transmitted from the control part 430 to the storage part 410 and continuously stored in the storage part 410 in real time.

The control part 430 loads information stored in the storage part 410 if the multifunctional storage system is normally operated again after being forcibly ended. In addition, it is determined using the information transmitted to the control part 430 that the multifunctional housing system is operated in the humidification mode (M)_Wet) Or in dehumidification mode (M)_{Dry matter}) The run is forced to end. When the humidification mode (M) is determined_Wet) When the operation is forcibly ended, the operation may be based on the humidification mode (M) before the forcible end_Wet) To flexibly adjust the forced dehumidifying time period of the receiving chamber 100.

For example, if the humidification mode (M) is performed_Wet)5 minutes, then the humidification mode (M) can be executed_Wet) For 5 minutes of the executed time. The humidity inside the receiving chamber 100 depends on the humidification mode (M)_Wet) The forced dehumidifying time period is not fixed to a specific value in order to perform an appropriate time period according to the humidity in the receiving chamber 100. In the present invention, even if the humidity sensor is not provided inside the storage chamber 100, the appropriate forced dehumidification can be performed in consideration of the humidity information of the storage chamber 100. In this way, it is not necessary to provide the humidity sensor inside the housing chamber 100 in order to implement the present invention, so that it is possible to prevent problems caused by frequent errors of the humidity sensor in advance.

When the multifunctional accommodating system is operated in a dehumidification mode (M)_{Dry matter}) When the dehumidification mode is forcibly ended, the dehumidification mode (M) is preset_{Dry matter}) The time period is not finished, that is, the state of the laundry is not a dry state to the extent that the user can wear it immediately. Therefore, even in the dehumidification mode (M)_{Dry matter}) When the operation is forcibly ended, forced dehumidification is also required, and the dehumidification mode (M) can be used_{Dry matter}) The remaining time period of the storage chamber 100 to set the forced dehumidification time period of the storage chamber. For example, in a preset dehumidification mode (M)_{Dry matter}) A dehumidification mode (M) until the multifunctional storage system is forcibly ended when the operation time is 20 minutes_{Dry matter}) Is the actual dehumidification mode (M)_{Dry matter}) The proceeding time period is 5 minutes, the forced dehumidification corresponding to 15 minutes as the remaining time period not performed may be performed.

In addition, as a modification of the above-described second embodiment, the control section 430 and the storage section 410 may be configured to transmit information on the start of the specific mode at the start of the specific mode. In the above-described modification, when the specific mode starts, the control section 430 transmits only information on the start of the specific mode to the storage section 410. At this time, the storage part 410 may be configured to individually check the executed time length of the specific mode, and may be configured to store information on the executed time length in real time or in units of seconds. When the multi-function housing system is forcibly ended, the storage part 410 may keep a state of storing information on the executed time period of the specific mode. In the above-described modification, the number of times of information transmission between control section 430 and storage section 410 can be reduced, thereby preventing in advance problems due to communication errors between control section 430 and storage section 410.

3) Third embodiment (forced dehumidification method based on end section)

"third embodiment" is described with reference to fig. 7 to 8B.

The sections are subdivided for each mode of the multi-functional storage system and are continuously stored in the storage section at the end of the respective section. Specifically, when the operation of the multifunctional storage system is the humidification mode (M)_Wet) Every time the humidification mode (M) is preset_Wet) When the subdivided section of the execution time period ends, information on the end of the corresponding section is stored in the storage section 410.

When the multifunction storage system is forced to end and then normally operates again, the control section 430 loads the storage information of the storage section 410. The information about the actual operation time period may be derived from information about the end interval within the specific pattern. The specific mode is a humidification mode (M)_Wet) Or a dehumidification mode (M)_{Dry matter})。

Humidification mode (M)_Wet) Is composed of N sections divided according to time, and represents a humidification mode (M) when the section is forcibly ended in the K +1 th section_Wet) Execution is performed up to the K-th interval. Is configured to perform forced dehumidification corresponding to the performed time period until the K-th section. Here, the corresponding forced dehumidification may refer to adjusting the temperature of the dehumidification portion 260 and the output of the fan unit 230 or adjusting the forced dehumidification period.

In more detail, if the humidification mode (M) is being performed_Wet) During which four intervals are completed, thenThe information on the completion of the four sections is stored in the storage unit 410. When the multi-function storage system is forcibly terminated while the 5 th section is in progress, the storage unit 410 is in a state of storing information on termination of the four sections. When the multifunctional housing system is normally operated again, the control part 430 is configured to load information on the end of four sections from the storage part 410 and to execute the humidification mode (M) up to the 4 th section_Wet) And forced dehumidification corresponding to the running time.

In addition, a dehumidification mode (M)_{Dry matter}) The dehumidification mode (M) is defined by M sections, and when the dehumidification mode is forcibly ended in the L +1 th section_{Dry matter}) The L-th section, that is, the forced dehumidification corresponding to the remaining time period as the time period from the L + 1-th section to the M-th section is performed. Image humidification mode (M)_Wet) Also, the corresponding forced dehumidification may mean adjusting the temperature of the dehumidification portion 260 and the output of the fan unit 230 or adjusting the forced dehumidification period.

In more detail, the dehumidification mode (M)_{Dry matter}) May consist of a total of 10 intervals. If in the dehumidification mode (M)_{Dry matter}) If four sections are completed in the process of (1), information on the end of the four sections is stored in the storage unit 410. When the multi-function housing system is forcibly ended while the 5 th section is in progress, the storage section 410 is in a state of storing information on the end of the four sections. When the multifunctional housing system is normally operated again, the control part 430 is configured to load information on the end of the four sections from the storage part 410 and to execute a dehumidification mode (M) as a time period from the 5 th section to the 10 th section_{Dry matter}) And forced dehumidification corresponding to the residual time.

The number of the above-mentioned sections is an example, and is not limited thereto, and may be set according to the selection of a designer, and the time length of each unit section may be formed differently in consideration of a saturated steam curve or a humidity curve.

In the foregoing specification, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but it is understood that it is only exemplary and that those skilled in the art can make various modifications and equivalent other embodiments according to the embodiments of the present invention. Therefore, the protection scope of the present invention should be defined by the claims.

Claims (13)

1. A multifunctional storage system which performs forced dehumidification after forced termination is characterized by comprising:

a storage chamber (100);

a machine room (200) that operates in a specific mode;

a storage unit (410) that receives and stores information about a specific mode when the specific mode ends; and

a control part (430) which controls the machine room (200) to operate in the specific mode,

wherein the storage part (410) is operative to store information about the specific mode at the end of the specific mode, and to transmit the information about the specific mode stored in the storage part (410) to the control part (430) when the multi-function storage system is normally operated after being forcibly ended,

the control part (430) controls to perform forced dehumidification of the receiving chamber (100) when it is determined that the operation is forcibly ended in any one of preset modes using the information on the specific mode, wherein the machine chamber (200) is operated to perform forced dehumidification of the receiving chamber (100).

2. A multiple function storage system according to claim 1, wherein the control portion (430) is operative to determine, if it is determined according to the specific mode, a humidification mode (M) in which humidified air is supplied to the storage chamber (100) when it is determined with the information on the specific mode to be forcibly ended in operation in any one of preset modes_Wet) Or a dehumidification mode (M) for dehumidifying the storage chamber (100)_{Dry matter}) When the operation is forcibly finished, the storage chamber (100) is forcedly dehumidified.

3. A multifunctional housing system according to claim 2, wherein the forced dehumidification of the housing chamber (100) by the control portion (430) is performed by the machine chamber (200) for a preset time period to the housing chamber (100).

4. A multi-functional storage system according to claim 2, wherein the control portion (430) is determining that the multi-functional storage system is in the humidification mode (M)_Wet) When the operation is forcibly finished, according to the humidification mode (M)_Wet) Controls a forced dehumidification duration of the receiving room (100) and determines that the multifunctional receiving system is in the dehumidification mode (M)_{Dry matter}) When the operation is forced to be finished, according to the information about the dehumidification mode (M)_{Dry matter}) Controls the forced dehumidification period of the receiving chamber (100).

5. A multifunctional housing system according to claim 4, wherein the information about the specific mode is stored in the storage section (410) at the end of the specific mode, with respect to the humidification mode (M)_Wet) And information on the operated time period of the dehumidification mode (M)_{Dry matter}) Is transmitted from the control part (430) in real time and stored in the storage part (410),

information on the humidification mode (M) stored in the storage part (410) when the multifunctional housing system is normally operated after being forcibly ended is transmitted to the control part (430)_Wet) And information on the operated time period of the dehumidification mode (M)_{Dry matter}) Is transmitted from the storage section (410) to the control section (430).

6. A multiple function storage system as claimed in claim 2, wherein the humidification mode (M) is based on the length of time that has been run in the control section (430)_Wet) Is divided into a 1 st interval to an Nth interval, wherein N is a natural number more than 1,

storing information on the specific pattern in the storage unit (410) at the end of the specific pattern, if a Kth section, which is a section between the 1 st section and the Nth section, ends and enters a K +1 th section, storing the information on the end of the Kth section in the storage unit (410),

when information on the specific mode stored in the storage part (410) is transmitted to the control part (430) when the multifunctional storage system is in normal operation after being forcibly ended, information on the end of the Kth section is transmitted from the storage part (410) to the control part (430),

when it is determined using the information on the specific mode that the multifunctional storage system is forcibly ended to perform control to forcibly dehumidify the storage chamber (100) in operation in any one of preset modes, if it is determined that the multifunctional storage system is in the humidification mode (M)_Wet) And forcibly ending in operation, the forced dehumidification period of the machine room (200) is determined by the humidification proceeding period which is the sum of the 1 st section to the Kth section.

7. A multifunctional storage system according to claim 2, wherein the dehumidification mode (M) is based on the length of time that has been run in the control portion (430)_{Dry matter}) Is divided into a 1 st interval to an Mth interval, wherein M is a natural number more than 1,

when information on a specific mode is stored in the storage unit (410) at the end of the specific mode, if an L-th section, which is a section between the 1 st section and the M-th section, ends and enters an L + 1-th section, the information on the end of the L-th section is stored in the storage unit (410) from the control unit (430),

when information on the specific mode stored in the storage part (410) is transmitted to the control part (430) when the multifunctional storage system is in normal operation after being forcibly ended, information on the end of the lth interval is transmitted from the storage part (410) to the control part (430),

controlling in determining to be forcibly ended in operation in any one of preset modes using information on the specific modeWhen forced dehumidification of the storage compartment (100) is performed, if it is determined that the multifunctional storage system is in the dehumidification mode (M)_{Dry matter}) The forced dehumidifying time period of the machine room (200) at the forced end of the operation is determined by the dehumidifying remaining time period which is the sum of the 1 st section to the L th section.

8. A multi-functional storage system according to claim 2,

the specific mode further includes:

preprocessing mode (M)_{Preparation of}) A discharge unit for discharging air to the storage chamber (100); and

post-processing mode (M)_{Rear end}) For supplying air to the receiving chamber (100),

wherein the control part (430) operates the machine room (200) to sequentially perform the pre-treatment mode (M) in a laundry management process of managing laundry in the receiving room (100)_{Preparation of}) The humidification mode (M)_Wet) The dehumidification mode (M)_{Dry matter}) And the post-processing mode (M)_{Rear end})。

9. A multi-function storage system according to claim 1, wherein the forced end of the multi-function storage system comprises:

a condition of interruption of power supply from a power source; and

a case where the multi-function housing system is forcibly ended regardless of the specific mode.

10. A multiple function storage system according to claim 1, wherein the memory portion (410) comprises an electrically erasable programmable read only memory.

11. A multi-functional storage system, characterized by comprising:

a storage chamber (100);

a machine room (200) operating to form the receiving room (100) into a specific pattern;

a storage unit (410) that receives and stores information regarding the mode of the storage chamber (100) when the mode of the storage chamber (100) ends; and

a control unit (430) that controls the operation of the machine room (200) in the specific mode,

wherein if a humidification mode (M) for supplying humidified air to the storage chamber (100) is determined according to the specific mode while the multifunctional storage system is normally operated after being forcibly ended, the humidification mode is performed_Wet) Or a dehumidification mode (M) for dehumidifying the storage chamber (100)_{Dry matter}) When the operation is forcibly terminated, the control unit (430) operates the machine room (200) to forcibly dehumidify the storage room (100).

12. A multi-functional storage system according to claim 11, wherein the machine room (200) comprises:

a dehumidification section (260) that dehumidifies the circulating air that flows through the housing chamber (100);

a circulating air inlet (141) and a circulating air outlet (142) which communicate the housing chamber (100) and the machine chamber (200);

a circulation filter unit (229) that supplies moisture to the circulation air supplied to the housing chamber (100) through the circulation air inlet (141); and

a fan unit (230) that circulates air in one direction,

wherein the humidification mode (M)_Wet) And the dehumidification mode (M)_{Dry matter}) In a state where the machine room (200) is isolated from the outside air,

in the humidification mode (M)_Wet) Then, the natural humidified air generated by the circulation filter unit (229) is supplied to the receiving chamber (100) through the fan unit (230) and circulated,

in the dehumidification mode (M)_{Dry matter}) Then, the air dehumidified by the dehumidifying part (260) is supplied to the receiving chamber (100) by the fan unit (230) and circulated,

when in the humidifying mode (M)_Wet) Or the dehumidification mode (M)_{Dry matter}) Is forcibly ended in operationIn this case, the dehumidifying part (260) and the fan unit (230) operate to forcibly dehumidify the receiving chamber (100).

13. A multifunctional housing system according to claim 12, wherein in a pre-treatment mode (M) of supplying air to the housing chamber (100)_{Preparation of}) And a post-processing mode (M)_{Rear end}) In the state that the machine room (200) is isolated from the outside air, only the fan unit (230) is operated to supply air to the storage room (100).

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