KR102647362B1 - Multi-function storage system performing preheating mode by measuring condenser temperature and method of perfoming preheating mode using thereof - Google Patents

Abstract

The present invention is a multi-functional storage system (1000) consisting of a machine room (100) and a compartment (200) where clothes are stored. It is located in the machine room (100) and includes an evaporator (112), a condenser (114), and a compressor (116). and a heat pump unit 110 including a pressure regulator; A moisture supply unit 120 coupled to the heat pump unit 110 and including a humidification filter 122; and a temperature measuring unit 130 that measures the temperature of the heat pump unit 110, wherein moisture is supplied to the humidifying filter 122 according to preset conditions, and the temperature measured by the temperature measuring unit 130 is supplied to the humidifying filter 122 according to preset conditions. A multi-functional storage system is provided in which the heat pump unit 110 operates when the temperature is below a preset value.

Description

Multi-function storage system performing preheating mode by measuring condenser temperature and method of perfoming preheating mode using the same}

The present invention is a multi-function storage system that operates a heat pump unit by measuring the condenser temperature and a method of performing a preheating mode using the same. Specifically, it is a technology that increases the drying efficiency of the multi-function storage system by pre-heating the machine room of the multi-function storage system.

Recently, air pollution due to fine dust, etc. has become a problem. Accordingly, devices related to air purification, such as air purifiers, are gaining attention.

However, since air purifiers can only purify the air in enclosed indoor spaces, it is difficult to remove all dust that may be on clothes after going out.

To remove this, physical methods such as opening clothes outdoors have been used, but these methods are difficult to use these days as outdoor air is highly polluted.

Accordingly, recently, clothing care machines have been developed and used to remove fine dust that may be stuck on clothes worn outdoors.

Meanwhile, the clothing care machine consists of a cabinet for storing clothing and a machine room equipped with devices for sterilizing, humidifying, or drying the clothes in the cabinet, and the machine room is equipped with a heat pump module.

In relation to the heat pump module, as the air in the refrigerator is circulated during drying, the moisture in the air is condensed in an evaporator to remove the moisture, and the air is heated in the condenser and supplied back to the refrigerator.

As moisture decreases during this drying operation, the load on the evaporator decreases, and the air passing through the condenser passes at a lower temperature because the condensation load on the evaporator is reduced.

As a result, as the temperature of the existing heated air decreases, the temperature of the air supplied into the refrigerator also decreases, resulting in a problem in which the drying efficiency of clothes stored in the refrigerator is significantly reduced.

In addition, when the user performs the drying mode of the clothes care machine, conventional technologies immediately enter the drying mode, and the drying mode is performed in a low temperature state in the machine room and interior, so even if the heat pump module operates, the user The desired drying efficiency cannot be achieved.

In other words, drying efficiency increases as the temperature inside the machine room and the cabinet increases, but performing the drying mode immediately without any preheating process to raise the temperature inside the machine room and the cabinet is very inefficient and has the problem of wasting a lot of power.

Meanwhile, Korean Patent Publication No. 10-2008-0004028, which is a prior art, discloses a clothing treatment device.

Specifically, the prior art includes: a cabinet provided with an interior space isolated from the outside to accommodate clothing, and the interior space selectively communicating with the outside through a door; a steam generator provided in the cabinet and supplying steam to the interior space; Additionally, the disclosure discloses a clothing treatment device including a heated air supply device provided in the cabinet and selectively supplying medium temperature heated air and high temperature heated air that is above room temperature to the interior space.

However, the above prior art also only discloses supplying heated air to the internal space where clothes are stored, and does not disclose any means for increasing drying efficiency within the cabinet.

Accordingly, there is a very high need for technology to preheat the machine room using a heat pump module to increase the drying efficiency of clothes stored in the machine.

(Patent Document 1) Korean Patent Publication No. 10-2008-0004028

The present invention was created to solve the above problems.

Specifically, we would like to propose a structure of a multi-functional storage system that can preheat the machine room when the temperature of the air in the machine room is below a preset value before starting the drying mode in the cabinet where clothes are stored.

In addition, using the structure of the multi-functional storage system, we would like to propose a method of preheating the machine room through a heat pump unit to increase the drying efficiency of clothes when the user executes the drying mode.

One embodiment of the present invention to solve the above problems is a multi-functional storage system 1000 consisting of a machine room 100 and a compartment 200 where clothes are stored. It is located in the machine room 100 and has an evaporator ( 112), a heat pump unit 110 including a condenser 114, a compressor 116 and a pressure regulator; A moisture supply unit 120 coupled to the heat pump unit 110 and including a humidification filter 122; and a temperature measuring unit 130 that measures the temperature of the heat pump unit 110; Includes, wherein moisture is supplied to the humidification filter 122 according to preset conditions, and when the temperature measured by the temperature measuring unit 130 is below a preset value, the heat pump unit 110 is operated, Provides a multi-functional storage system.

In addition, the temperature measuring unit 130 is preferably formed to measure the temperature of the condenser 114 of the heat pump unit 110.

In addition, the heat pump unit 110 is preferably operated until the temperature of the condenser 114 reaches a preset value to preheat the machine room 100.

In addition, the temperature measuring unit 130 is formed to further measure the temperature inside the machine room 100, and when the temperature inside the machine room 100 is below a preset value, the heat pump unit 110 is operated. It is desirable to be

Additionally, when the heat pump unit 110 is operated, it is preferable that the supply of moisture to the humidification filter 122 is stopped.

In addition, a fan unit 140 that circulates the air in the machine room 100 from the evaporator 112 to the condenser 114; It further includes, wherein the machine room 100 is located in the lower part of the storage room 200, and first and second flow path conversion units 160 and 170 are provided between the machine room 100 and the storage room 200. When the fan unit 140 is operated while both the first and second flow path switching units 160 and 170 are operated in the first position, the air in the machine room 100 and the interior 200 is They communicate and circulate together, and when both the first and second flow path switching units 160 and 170 are operated in the second position, air communication between the machine room 100 and the interior 200 is cut off from each other, When the fan unit 130 is operated, it is preferable that external air is sucked into the machine room 100 and then discharged again through the exhaust duct 190 of the machine room 100.

In addition, the multi-functional storage system 1000 has a drying mode in which clothes stored in the cabinet 200 are dried while both the first and second flow path switching units 160 and 170 are operated in the first position. However, it is preferable that the heat pump unit 110 is operated to preheat the machine room 100 for a preset time before performing the drying mode.

Additionally, when the heat pump unit 110 is operated to preheat the machine room 100, it is preferable that the fan unit 130 stops operating.

In addition, the present invention is a method of performing a preheating mode of the above-described multi-functional storage system, including (a) measuring the temperature of the condenser 114 in the temperature measuring unit 130 (S100); and (b) when the temperature of the condenser 114 is below the preset value, the heat pump unit 110 is operated to preheat the machine room 100 (S110); Provides a method of performing a preheating mode of a multi-functional storage system, including.

In addition, the step (b) (S110) includes (b-1) a step (S112) of stopping the operation of the fan unit 140 that circulates air in the machine room 100 and the interior 200; It is desirable to further include.

In addition, the step (b) (S110) includes (b-2) a step (S114) in which the supply of moisture to the humidification filter 122 is stopped when the heat pump unit 110 is operated; It is desirable to further include.

The present invention includes a temperature measuring unit that measures the temperature of the heat pump unit, and when the measured temperature is below a preset value, the temperature inside the machine room can be increased by operating the heat pump unit to preheat the inside of the machine room. Accordingly, the user can preheat the machine room before performing the drying mode.

In this way, by increasing the temperature of the air circulating in the machine room and the interior of the cabinet, drying efficiency can be increased when performing the drying mode of the multi-functional storage system, and ultimately, the clothes stored in the interior are kept in a more comfortable condition, thereby improving multi-functional storage. It has the effect of increasing consumer confidence in the system.

Figure 1 is a perspective view of the multi-functional storage system according to the present invention with the case removed.
Figure 2 is a schematic diagram of the machine room of the multi-functional storage system according to the present invention.
Figure 3 is a perspective view of the machine room of the multi-functional storage system according to the present invention.
Figure 4 is a perspective view from the opposite side of the perspective view shown in Figure 3.
Figure 5 is a perspective view of the machine room of the multi-functional storage system according to the present invention as seen from the left.
Figure 6 is a perspective view of the machine room of the multi-functional storage system according to the present invention viewed from the front.
Figure 7 is a schematic diagram schematically showing air circulation in the machine room and the storage room when both the first and second flow path switching units of the multi-functional storage system according to the present invention are located in the first position.
Figure 8 is a schematic diagram schematically showing air circulation in the machine room and the storage room when both the first and second flow path switching units of the multi-functional storage system according to the present invention are located in the second position.
Figure 9 is a flowchart of a method of performing a preheating mode of a multi-functional storage system according to the present invention.

Hereinafter, for a detailed explanation of the machine room and interior, the description will be made based on drawings of the multi-functional storage system with the case removed, and the direction toward which the exhaust duct and intake duct face is defined as "front."

In addition, this explanation assumes that the storage compartment is located at the top of the machine room, and based on this, the left and right sides of the multi-functional storage system are defined.

1. Description of the configuration of the multi-functional storage system for performing preheating mode

Hereinafter, the structure of the multi-functional storage system according to the present invention will be described with reference to FIGS. 1 to 6.

Figure 1 is a perspective view of the multi-functional storage system according to the present invention with the case separated.

Referring to FIG. 1, the inside 200 is located at the upper part of the machine room 100, and is formed to store clothes in the inside 200. The machine room 100 is equipped with the necessary means for drying, cleaning, and humidifying the clothes. are provided.

At this time, an exhaust duct 190 is formed in the upper part of the front side of the machine room 100 to discharge air from the machine room 100 or the inside of the cabinet 200 to the outside, and at the lower part, an exhaust duct 190 is formed to exhaust air from the machine room 100 or the inside of the cabinet 200 to the outside. ) An intake duct 192 is formed to allow suction into the air.

Additionally, for this air circulation, a fan unit 130 is provided at the rear of the machine room 100.

Figure 2 is a schematic diagram of the machine room of the multi-functional storage system according to the present invention.

Referring to FIG. 2, the multi-functional storage system according to the present invention includes a heat pump unit 110, a moisture supply unit 120, a temperature measurement unit 130, and a control unit 150.

The heat pump unit 110 includes an evaporator 112, a condenser 114, a compressor 116, and a pressure regulator (not shown), and the refrigerant circulates through the cycle of the heat pump unit 110, exchanging heat with the surrounding air. It is formed to do. Meanwhile, description of the process in which the refrigerant circulates through the heat pump unit 110 will be omitted.

The temperature measuring unit 130 is formed to measure the temperature of the heat pump unit 110, and is preferably formed to measure the temperature of the condenser 114 of the heat pump unit 110.

This is the same as when the heat pump unit 110 is not operated for a considerable period of time, as the temperatures of the components of the heat pump unit 110 all reach thermal equilibrium, but the heat pump unit 110 is not operated in dry mode by the user. This is because the temperatures of the components may be different if they have already been started before performing.

When the heat pump unit 110 is operated, the temperature of the condenser 114 is formed to be higher than the temperature of the evaporator 112, and the evaporator 112 is formed to have a lower temperature than the air in the machine room 110. It is desirable to determine whether to start preheating based on the temperature of (114) in performing an appropriate preheating mode.

Meanwhile, the temperature measuring unit 130 includes a temperature sensor and is configured to measure the temperature of the condenser 114 and transmit the measured temperature information to the control unit 150.

Preferably, when the temperature of the condenser 114 measured by the temperature measuring unit 130 is 18 degrees or less, the control unit 150 controls the heat pump unit 110 to operate.

At this time, the specific temperature at which the heat pump unit 110 operates and stops can be adjusted according to the selection of the designer or user.

In addition, the temperature measuring unit 130 is formed to measure the temperature of the condenser 114 in real time, and when the temperature of the condenser 114 reaches 40 degrees, the machine room 110 uses the heat pump unit 110. ) can be stopped from performing the preheating mode.

At this time, after the preheating mode is stopped, the heat pump unit 110 continues to operate and the fan unit 140 operates, so that a drying mode for drying clothes stored in the refrigerator can be performed.

Meanwhile, the temperature measuring unit 130 may be formed to directly measure the temperature of the air inside the machine room 110 in addition to the temperature of the condenser 114. When the temperature of the air inside the machine room is below a preset value, the control unit 150 It may be configured to operate the heat pump unit 110.

In addition, when performing the drying mode of the machine room 100 and the interior 200, the supply of moisture to the humidification filter 122 may be stopped, which is due to stopping the supply of moisture to the humidification filter 122, thereby causing drying. This is to increase efficiency.

When the fan unit 140 is operated, the air in the machine room 100 and the interior 200 can be circulated, and the operation of the fan unit 140 is stopped so that the temperature of the machine room 100 increases intensively. In this state, the heat pump unit 110 can be operated, and the operation of the fan unit 140 is controlled by the control unit 150.

2. Description of other components of the multi-functional storage system

Referring back to FIG. 2, the multi-functional storage system 1000 according to the present invention includes a moisture supply unit ( 120).

At this time, the moisture supply water tank 124 is provided at the lower part of the humidification filter 122 to store water falling from the humidification filter 122.

In addition, the water supply unit 120 is connected to the water supply tank 124 and includes a water supply pump 126 configured to pump up the water in the water supply tank 124.

Accordingly, the humidification filter 122 is formed so that the water stored in the water supply tank 124 is supplied by the water supply pump 126 and is formed so that the water stored in the water supply tank 124 can circulate.

At this time, the water supplied to the humidification filter 122 continues to be consumed during the evaporation process, and the water in the moisture supply tank 124 cannot continue to circulate, so it is necessary to replenish water for circulation.

Accordingly, the multi-functional storage system 1000 according to the present invention is configured to store water and further includes a water tank 104 connected to the water pump 102.

When the water level in the water supply tank 124 of the water supply unit 120 is below a preset value, the water pump 102 operates to supply water to the humidification filter 122, thereby It is formed to replenish evaporated water.

3 to 6, the humidification heater unit 128 serves to instantaneously heat the water passing through the humidification heater unit 128, and the water heated through the humidification heater unit 128 is It is supplied to the humidification filter 122.

The moisture supply pump 142 is formed to raise the water stored in the moisture supply tank 124, and serves to circulate water in the order of the moisture supply tank 124, the humidification heater unit 128, and the humidification filter 122. do.

At this time, one water supply pump 142 may be provided, but preferably, the water supply pump 142 is formed as a pair of two pumps, and operate alternately according to a preset cycle, which It is possible to prevent failures due to load concentration on a specific pump.

The humidifying filter 122 provided inside the machine room 100 is formed to be coupled to the front of the evaporator 112, and accordingly, based on the air circulation direction, the air is transferred to the humidifying filter 122, the evaporator 112, and the condenser. (114) It is formed to flow in the order.

In this way, the air circulating in the machine room 100 or the interior 200 passes through the humidifying filter 122 before passing through the heat pump unit 110, and moisture is supplied into the air, thereby passing through the heat pump unit 110. It can replenish the moisture content in the air.

Meanwhile, the control unit 150 that controls the operation of the heat pump unit 110 is preferably formed of a printed circuit board (PCB). Referring to FIG. 3, the lower part of the humidification heater unit 128 It is provided in .

At this time, the control unit 150 is formed to control the operation of the water supply pump 102 connected to the water supply tank 104, and is formed to control the operation of the water supply pump 126 connected to the water supply tank 124. , the control unit 150 is formed to also control the operation of the humidification heater unit 128.

Figure 5 is a perspective view of the machine room of the multi-functional storage system according to the present invention as seen from the left.

Referring to FIG. 5, the humidification heater unit 128 is disposed on the upper part of the control unit 150.

At this time, the humidification heater unit 128 can preferably be formed to heat water up to 80°C, and the humidification filter 122 is supplied with moisture heated to 80°C or close to 80°C, thereby producing water by itself. This has the effect of increasing the temperature of the air in the machine room 100.

At this time, since moisture is not continuously supplied to the humidification filter 122 at all times, water is supplied to the humidification filter 122 when the moisture supply pump 126 operated by the control unit 150 is operated. It is preferably formed to wet the humidifying filter 122.

Meanwhile, if there is no water stored in the first moisture supply tank 124, the humidification filter 122 cannot receive water from the moisture supply tank 124.

Accordingly, the water stored in the water supply tank 104 is supplied to the humidification filter 122 by the water pump 102 until the water level in the water supply tank 124 reaches a preset value.

In addition, even if it is not in the initial state, when the level of water stored in the water supply tank 124 is below the preset value, the water pump 102 operates to supply water to the humidification heater unit 128 to instantaneously heat it, and then heats it. It is formed to supply the humidified water to the humidifying filter (122).

Accordingly, the water level in the water supply tank 124 may gradually rise to a preset value, and when it reaches the preset value, the water in the water supply tank 124 is circulated and supplied to the humidification filter 122. is formed

Figure 6 is a perspective view of the machine room of the multi-functional storage system according to the present invention viewed from the front.

Referring to FIG. 6, on the front side of the machine room 100, a water pump 102 connected to the water tank 104 and a drain pump 106 connected to the drain tank 105 are provided.

On the other hand, when the water level of the water tank 104 is below a predetermined value before operation of the multi-functional storage system 1000, an alarm may be issued to the user to replenish water, and the water level of the drain tank 105 may be set to a predetermined value. When it is determined that the water exceeds the value and there is a possibility of overflow, an alarm may be sent to the user to discard the water.

The operation of the above-described configurations is preferably operated in a preheating mode before the drying mode and humidifying mode of the multi-functional storage system 1000 are performed in order to increase the operating efficiency of these modes.

In addition, the designer can add a separate preheating mode so that the user can select it, and the preheating mode can be performed by the user before the drying mode, humidifying mode, and cleaning mode are performed, or automatically according to a predetermined cycle. It may be configured to perform a preheating mode.

3. Operation of the first and second flow path switching units in preheating mode of the multifunctional storage system

Referring to FIG. 4, first and second flow path switching units 160 and 170 are provided between the machine room 100 and the storage unit 200.

The first flow path switching unit 160 serves to control whether the air between the machine room 100 and the interior 200 communicates or is blocked from each other.

The second flow path switching unit 170 serves to control whether the air in the machine room 100 communicates to the outside or into the interior of the machine 200.

At this time, it is preferable that the first and second flow path switching units 160 and 170 operate identically to each other. Specifically, when the first flow path switching unit 160 is operated in the first position, the second flow path switching unit 160 is operated in the first position. The switching unit 170 is also operated to the first position, and when the first flow path switching unit 160 is operated to the second position, the second flow path switching unit 170 is also preferably operated to the second position.

Specifically, the first and second flow path switching units 160 and 170 are internally provided with a rotating member configured to rotate about an axis, and the rotating member is configured to operate in a vertical or horizontal direction.

Hereinafter, the case where the rotating members of the first and second flow path switching units 160 and 170 are operated in the vertical direction is defined as the first position, and the case where the rotating members are operated in the horizontal direction is defined as the second position. .

FIG. 4 shows a state in which both the first and second flow path switching units 160 and 170 are operated in the first position.

Figure 7 is a schematic diagram schematically showing the air circulation in the machine room and the storage room when both the first and second flow path conversion units of the multi-functional storage system according to the present invention are located in the first position, and Figure 8 is a schematic diagram showing the air circulation in the machine room and the storage room. This is a schematic diagram schematically showing the air circulation in the machine room and the interior when both the first and second flow path switching units of the multi-functional storage system according to the invention are located in the second position.

Referring to FIG. 7, as the first flow path switching unit 160 is operated in the vertical direction, which is the first position, the air in the refrigerator 200 and the machine room 100 is formed to communicate with each other.

In addition, as the second flow path switching unit 170 is also operated in the vertical direction, which is the first position, the air in the furnace 200 and the machine room 100 communicates with each other, and at the same time, the air in the machine room 100 and the outside is blocked. is formed

At this time, when the fan unit 130 is operated while both the first and second flow path switching units 160 and 170 are located in the first position, the air in the machine room 100 and the interior 200 is They are connected and circulate together.

Referring to FIG. 8, as the first flow path switching unit 160 is operated in the horizontal direction, which is the second position, the air in the refrigerator 200 and the machine room 100 is formed to be blocked from each other.

In addition, as the second flow path switching unit 170 is also operated in the horizontal direction, which is the second position, the air in the interior 200 and the machine room 100 is blocked from each other, and at the same time, the air in the machine room 100 and the outside is communicated. is formed

In this way, when both the first and second flow path switching units 160 and 170 are operated in the second position, air communication between the machine room 100 and the interior 200 is blocked from each other, and the fan unit 130 ) is operated, external air is sucked into the machine room 100 and then discharged back to the exhaust duct 190 of the machine room 100, which is preferably used in a clean mode.

In this way, the multi-functional storage system 1000 according to the present invention processes the clothes stored in the cabinet 200 and also performs the role of purifying the air in the space where the multi-functional storage system 1000 is located. can do.

For this purpose, the machine room 100 is further equipped with an air cleaning unit 180, and when the fan unit 130 is operated while both the first and second flow path switching units 160 and 170 are operated in the second position, , the external air is configured to pass through the air cleaning unit 180 and then be discharged into the exhaust duct 190 of the machine room.

Meanwhile, in relation to the preheating mode of the multi-functional storage system 1000 according to the present invention, with both the first and second flow path switching units 160 and 170 operated in the first position, the heat pump unit 110 The machine room 100 can be preheated by operating.

At this time, it may be configured to operate only the heat pump unit 110 without operating the fan unit 130.

Meanwhile, a drying mode for drying clothes stored in the cabinet 200 is performed while both the first and second flow path switching units 160 and 170 are operated in the first position. However, before performing the drying mode, a preset drying mode is performed. During the time, the heat pump unit 110 may be operated to preheat the machine room 100, and the designer may be able to adjust the preset time.

In addition, in the preheating mode, the machine room 100 can be preheated by operating the heat pump unit 110 while both the first and second flow path switching units 160 and 170 are operated in the second position, This too can be configured to operate only the heat pump unit 110 without operating the fan unit 130.

4. How to perform preheating mode of a multifunctional storage system

Figure 9 is a flowchart of a preheating method for a multi-functional storage system according to the present invention.

Referring to FIG. 9, the method of performing the preheating mode of the multi-functional storage system 1000 according to the present invention includes measuring the temperature of the condenser 114 in the temperature measuring unit 130 (S100) and the temperature of the condenser 114. When the temperature is below the preset value, the heat pump unit 110 is operated to preheat the machine room 100 (S110).

At this time, step S110 may further include a step S112 in which operation of the fan unit 140 that circulates air in the machine room 100 and the interior 200 is stopped.

As described above, when the fan unit 140 is operated, the air in the machine room 100 and the interior 200 is circulated, and the fan unit 140 is operated when the preheating mode is completed and the drying mode is performed. This is desirable to maximize the preheating efficiency of the air inside the machine room 100.

In addition, step S110 may further include a step S114 in which the supply of moisture to the humidification filter 122 is stopped when the heat pump unit 110 is operated.

This may affect drying efficiency when performing the drying mode due to moisture evaporating from the humidifying filter 122 by stopping the supply of moisture to the humidifying filter 122. In the process of performing the preheating mode, the humidifying filter 122 It is advisable to stop providing moisture.

Meanwhile, a separate member that opens and closes the intake duct may be further included, and accordingly, the preheating mode is performed after closing the intake duct while the fan unit 130 is not operating, thereby maximizing preheating efficiency. there is.

Above, 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 these are merely illustrative examples, and various modifications and equivalent alternatives can be made by those skilled in the art from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present invention should be determined by the scope of the patent claims.

1000: Multifunctional storage system
100: Machine room
200: Gonae
110: Heat pump unit
112: Evaporator
114: condenser
116: Compressor
118: pressure regulator
120: Moisture supply unit
122: Humidification filter
124: Hydration tank
128: Humidification heater unit
130: Temperature measurement unit
140: fan unit
142: Hydration pump
144: Hydration tank
150: control unit
152: Current measuring unit
160: 1st euro conversion unit
170: Second Euro conversion unit
180: Air purification unit

Claims (11)

A multi-functional storage system (1000) consisting of a machine room (100) and a compartment (200) where clothes are stored,
A heat pump unit 110 located in the machine room 100 and including an evaporator 112, a condenser 114, a compressor 116, and a pressure regulator;
A moisture supply unit 120 coupled to the heat pump unit 110 and including a humidification filter 122;
a temperature measuring unit 130 that measures the temperature of the heat pump unit 110;
A fan unit 140 that circulates the air in the machine room 100 from the evaporator 112 to the condenser 114;
First and second flow path switching units 160 and 170 provided between the machine room 100 and the interior 200; and
It includes; an intake duct opening and closing member that opens and closes the intake duct 192 of the machine room 100,
When the first and second flow path switching units 160 and 170 are both operated in the first position and the fan unit 140 is operated while the intake duct opening and closing member closes the intake duct 192, the While the machine room 100 and the interior of the furnace 200 are blocked from communicating with the outside, the air in the machine room 100 and the interior of the furnace 200 communicates and circulates together,
When both the first and second flow path switching units 160 and 170 are operated in the second position, air communication between the machine room 100 and the interior 200 is blocked, and the fan unit 140 When activated, external air is sucked into the intake duct 192 of the machine room 100 and then discharged again through the exhaust duct 190 of the machine room 100,
Moisture is supplied to the humidifying filter 122 according to preset conditions,
A humidifying mode in which humidified air generated by moisture supplied to the humidifying filter 122 is provided to the interior 200, and the first and second flow path switching units 160 and 170 are all operated in the first position, When a command to perform a dry mode is input among the dry modes in which dry air is provided to the interior 200 while the intake duct opening and closing member closes the intake duct 192, the temperature is measured by the temperature measuring unit 130. When the temperature is below the preset value, the heat pump unit 110 is operated to increase the temperature inside the machine room 100, and the preheating mode is performed before the drying mode,
When the heat pump unit 110 is operated, the supply of moisture to the humidification filter 122 is stopped and the operation of the fan unit 140 is stopped.
Multifunctional storage system.
According to claim 1,
The temperature measuring unit 130 is formed to measure the temperature of the condenser 114 of the heat pump unit 110,
Multifunctional storage system.
According to claim 1,
The heat pump unit 110,
The condenser 114 is operated until the temperature reaches a preset value to preheat the machine room 100.
Multifunctional storage system.
According to claim 1,
The temperature measuring unit 130,
It is formed to further measure the temperature inside the machine room 100,
When the temperature inside the machine room 100 is below a preset value, the heat pump unit 110 is operated,
Multifunctional storage system.
delete delete delete delete A method of carrying out the preheating mode of the multifunctional storage system according to any one of claims 1 to 4, comprising:
(a) measuring the temperature of the condenser 114 by the temperature measuring unit 130 (S100); and
(b) when the temperature of the condenser 114 is below the preset value, the heat pump unit 110 is operated to preheat the machine room 100 (S110); Including,
How to perform preheating mode for multifunctional storage systems.
According to clause 9,
In step (b) (S110),
(b-1) stopping the operation of the fan unit 140 that circulates the air in the machine room 100 and the interior 200 (S112); Containing more,
How to perform preheating mode for multifunctional storage systems.
According to clause 9,
In step (b) (S110),
(b-2) when the heat pump unit 110 is operated, the supply of moisture to the humidification filter 122 is stopped (S114); Containing more,
How to perform preheating mode for multifunctional storage systems.

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