KR20220107559A - Washing machine - Google Patents

Abstract

The present invention provides a washing machine comprising: a first housing having an opening and a space in which a drum accommodating laundry is inserted; a second housing coupled to the first housing; and a storage tank for storing carbon dioxide supplied to the drum, wherein carbon dioxide is injected into the drum to perform washing, and the storage tank includes a case forming the exterior and a supply pipe having an outlet disposed to be higher than the height of liquid carbon dioxide stored in the case so as to supply the liquid carbon dioxide to the case. According to the washing machine of the present invention, when the liquid carbon dioxide enters the storage tank, the liquid furnace does not fluctuate due to flow or evaporation.

Description

washing machine

The present invention relates to a washing machine, and more particularly, to a washing machine that performs laundry treatment such as washing using carbon dioxide.

In a washing machine using carbon dioxide, gaseous carbon dioxide and liquid carbon dioxide are filled throughout the washing tub during washing and rinsing. In order to do laundry using carbon dioxide, carbon dioxide is filled in the washing tub from the storage tub, and after washing, the carbon dioxide is drained from the washing tub to the distillation tub, and the carbon dioxide is reused by putting it into the storage tub. In addition, in the washing tub, a pulley is connected to a drive shaft to rotate the drum, and it is common to rotate the drum by connecting the motor pulley and the drum pulley with a belt.

A washing machine using carbon dioxide circulates through external charging, supply, washing, distillation, and charging cycles. The storage tank stores liquid carbon dioxide and supplies liquid carbon dioxide to the washing tub when washing is required, and then fills the liquefied carbon dioxide after distillation. perform the function There is a water level sensor next to the storage tank to detect the level of liquid carbon dioxide in the storage tank. As the gaseous carbon dioxide changes to liquid carbon dioxide while passing through the compressor, the liquid carbon dioxide ejected into the storage tank has a large pressure change, making it difficult to measure the level.

In addition, when the inlet/outlet structure through which the gaseous carbon dioxide is moved to the storage tank is located at the upper portion of the storage tank, the storage tank mounting height is increased, so that there is a problem that the size of the overall system is increased.

An object of the present invention is to provide a washing machine with an improved storage tank liquid inlet structure so that the liquid oil level is not shaken by flow or evaporation when liquid carbon dioxide enters the storage tank.

In addition, the washing machine according to the present invention is to provide a washing machine capable of reducing the overall height of the washing machine.

SUMMARY OF THE INVENTION The present invention is to solve the above problems, and the present invention provides a washing machine capable of reducing environmental pollution by reducing the amount of carbon dioxide used during laundry treatment such as washing.

In addition, the present invention provides a washing machine capable of reducing the size of a pressure-resistant container using carbon dioxide by reducing the amount of carbon dioxide used.

In addition, the present invention provides a washing machine capable of providing an environment capable of repairing a rotating drum while accommodating laundry.

In addition, the present invention provides a washing machine capable of reducing the space occupied by the washing machine by reducing the space occupied by the motor assembly for rotating the drum.

The present invention also provides a washing machine capable of stably operating the washing machine by maintaining the same pressure in a washing space in which a drum is disposed and a driving space in which a motor is disposed.

According to the present invention, it is possible to form a flow path through which liquid carbon dioxide moves through the lower part of the storage tank and gaseous carbon dioxide moves through the upper part.

In the present invention, since the supply pipe inserted into the storage tank rises above the maximum liquid oil level, even when liquid carbon dioxide is discharged into the storage tank, it flows down along the upper surface of the storage tank, so it does not shake the liquid oil level, thereby maintaining a stable oil level. It is possible to measure a stable water level value, so that the control can be reliable.

In addition, by raising the end of the supply pipe on the liquid inlet side of the storage tank to the maximum oil level or more, the liquid carbon dioxide flows along the inside of the storage tank, thereby maintaining a stable water level.

In addition, in the present invention, the storage tank gas suction/discharge unit is located on the side of the storage tank, and the inner pipe outlet connected to the suction/discharge unit is located on the upper surface of the storage tank, so that the storage tank height is reduced, thereby configuring a compact washing machine as a whole.

According to the present invention, a partition is installed to separate the interior of the washing tub into a washing unit and a motor unit so that liquid carbon dioxide used as a washing solvent does not flow into the motor unit. The partition wall may be made of a detachable part. In addition, by installing a motor directly on the rotating shaft of the washing drum to minimize unnecessary space in the motor unit, the amount of carbon dioxide used when processing clothes can be reduced, and the distillation tank and storage tank can be miniaturized, thereby reducing the overall size of the washing machine. .

By providing a through hole in the upper part of the partition wall so that the pipe of the heat exchanger disposed on the partition wall passes, gaseous carbon dioxide can move between the washing unit and the motor unit, thereby maintaining pressure balance between the washing unit and the motor unit.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; It provides a washing machine comprising a; a second housing that seals one surface of the partition wall and is coupled to the first housing.

In addition, the present invention is a first housing in which an opening is formed and a space in which a drum in which laundry is accommodated is inserted; a partition wall sealing the opening and coupled to the first housing; a second housing that seals one surface of the barrier rib and is coupled to the first housing, wherein the barrier rib contains liquid carbon dioxide injected into the space provided by the first housing and the barrier rib, the second housing and the barrier rib It provides a washing machine characterized in that it blocks movement in a space provided by

In addition, the present invention is a first housing in which an opening is formed and a space in which a drum in which laundry is accommodated is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein the size of the opening is larger than the size of the cross section of the drum. Accordingly, an operator can access and maintain the drum through the opening.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein the first housing includes a first flange formed along the opening, and the second housing is connected to the first flange It provides a washing machine including a second flange to be coupled.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein the partition wall includes a first through hole through which the rotation shaft of the motor passes, and a second through hole through which gaseous carbon dioxide moves A washing machine is provided.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein a heat exchanger through which a refrigerant moves is disposed in the partition wall, the heat exchanger being formed by the first housing and the partition wall A washing machine is provided in the space. and a motor assembly coupled to the partition wall, wherein the motor assembly includes a stator, a rotor, and a bearing housing.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein a heat exchanger through which a refrigerant moves is disposed in the partition wall, the heat exchanger being formed by the first housing and the partition wall A washing machine is provided in the space. A washing machine comprising a motor assembly coupled to the partition wall, the motor assembly including a stator, a rotor, and a bearing housing, wherein the bearing housing has a communication hole through which external air can flow in or out.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein a heat exchanger through which a refrigerant moves is disposed in the partition wall, the heat exchanger being formed by the first housing and the partition wall A washing machine is provided in the space. a motor assembly coupled to the partition wall, the motor assembly including a stator, a rotor, and a bearing housing, an O-ring is disposed at a portion where the bearing housing is coupled to the partition wall, and the O-ring contains liquid carbon dioxide A washing machine that prevents movement to a space opposite to the bulkhead is provided.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, and includes a storage tank for storing carbon dioxide supplied to the drum.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; It provides a washing machine including a distillation chamber for distilling liquid carbon dioxide used in the drum; and a second housing that seals one surface of the partition wall and is coupled to the first housing.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein the first housing and the second housing are coupled to form a closed space, and the closed space is on the partition wall It provides a washing machine, characterized in that divided by.

The present invention includes: a first housing having an opening and a space in which a drum containing laundry is inserted; a partition wall sealing the opening and coupled to the first housing; and a second housing that seals one surface of the partition wall and is coupled to the first housing, wherein carbon dioxide is injected into the drum to perform washing, and the partition wall is a space provided by the first housing and the partition wall It provides a washing machine characterized in that it blocks the liquid carbon dioxide injected into the second housing from moving into the space provided by the partition wall.

The size of the opening may be larger than the size of the cross-section of the drum.

It is possible that the size of the opening is larger than the size of the maximum cross-section of the drum.

The size of the opening may be larger than the size of the maximum cross-section of the space of the first housing.

The size of the opening may be kept the same up to the central portion of the first housing.

The first housing may include a first flange formed along the opening, and the second housing may include a second flange coupled to the first flange.

A seating groove to which the partition wall is coupled may be formed along the opening in the first flange.

A first seating surface extending in a radial direction rather than a circumference of the seating groove is provided on the first flange, and a second seating surface coupled to the first seating surface in surface contact with the second flange may be provided. .

The partition wall may include a first through hole through which the rotation shaft of the motor passes, and a second through hole through which gaseous carbon dioxide moves.

The second through-hole may be disposed at a higher position than the first through-hole.

It is possible to further include a heat exchanger coupled to the partition wall, and a refrigerant pipe moving in the heat exchanger can pass through the second through hole.

The second through hole may be two separate holes.

A heat exchanger through which a refrigerant moves may be disposed in the partition wall, and the heat exchanger may be disposed in a space formed by the first housing and the partition wall.

A heat insulating member may be disposed between the heat exchanger and the partition wall.

The heat exchanger may include a bracket coupled to the partition wall, and the bracket may be fixed to the partition wall by a bolt passing through the partition wall and a cap nut coupled to the bolt.

and a motor assembly coupled to the partition wall, wherein the motor assembly may include a stator, a rotor, and a bearing housing.

It is possible to include a rotation shaft disposed on the bearing housing, one end of the rotation shaft coupled to the rotor, and the other end of the rotation shaft coupled to the drum.

A sealing part may be disposed around the rotation shaft, and the sealing part may be disposed to be exposed to a space provided by the first housing and the partition wall.

The sealing portion may prevent liquid carbon dioxide from moving to the space opposite to the partition wall.

The bearing housing may have a communication hole through which external air can be introduced or discharged.

The rotation shaft may have a first flow path and a second flow path through which air can be introduced or discharged to be spaced apart from each other.

The first flow passage and the second flow passage may be formed in a radial direction from the center of the rotation shaft.

It is possible that a connection flow path connecting the first flow passage and the second flow passage is formed.

The connection flow path may be disposed at a rotation center of the rotation shaft, and may be vertically connected to the first flow path and the second flow path, respectively.

An O-ring is disposed at a portion where the bearing housing is coupled to the partition wall, and the O-ring prevents liquid carbon dioxide from moving to a space opposite to the partition wall.

An O-ring cover for preventing separation of the O-ring is coupled to the O-ring, and it is possible to include a storage tank for storing carbon dioxide supplied to the drum.

It is possible to include a distillation chamber for distilling the liquid carbon dioxide used in the drum.

It is possible to include a filter that filters out contaminants when discharging the liquid carbon dioxide used in the drum.

It is possible to include a compressor for reducing the pressure inside the drum.

The first housing and the second housing may be combined to form a closed space, and the closed space may be divided by the partition wall.

According to the present invention, since the liquid carbon dioxide discharged into the storage tank does not cause a large change in the level of the liquid carbon dioxide stored therein in the storage tank, accurate level detection is possible.

In addition, according to the present invention, the size of the storage tank can be reduced, thereby reducing the space required for the washing machine to be installed.

According to the present invention, since the amount of carbon dioxide used is reduced, the amount of carbon dioxide that needs to be reprocessed after use can be reduced, and the energy efficiency of the entire system can be improved. In addition, since the amount of carbon dioxide used is reduced, the size of the tank for storing carbon dioxide that must be stored before use can be reduced, so that the size can be improved to have a smaller overall size.

In particular, the amount of carbon dioxide used is reduced compared to the prior art. This reduces the amount of carbon dioxide that has to be reprocessed after use. Since the amount of carbon dioxide used is reduced, the capacity of the tank for storing carbon dioxide as well as the overall size of the washing machine for using carbon dioxide may be reduced. In addition, since the amount of carbon dioxide to be reprocessed after use is reduced, the time taken for washing or rinsing may also be reduced.

In addition, according to the present invention, various parts such as a drum can be separated from all parts to provide an environment for the operator to access and repair. In addition, by providing a structure in which various parts can be combined to produce an actual product, an operator can easily manufacture a washing machine using carbon dioxide.

In addition, according to the present invention, since the stator and the rotor are arranged together around the rotating shaft that rotates the drum, the space occupied by the motor assembly is reduced, so that the size of the washing machine can be reduced. In addition, since the coupling relationship of the components for rotating the drum is simplified, noise can be reduced when rotating the drum, and the efficiency of power transmission can be improved.

Also, according to the present invention, liquid carbon dioxide does not flow into the driving space where the motor is disposed, but gaseous carbon dioxide can flow into the driving space, so that the drum can be rotated in a state in which the pressure balance between the washing space and the driving space is maintained. Therefore, when the washing machine is operated, the drum can be rotated stably. In addition, since gaseous carbon dioxide is filled in the driving space, the amount of carbon dioxide used when processing clothes such as washing may be reduced.

1 is a view for explaining the concept of an embodiment of the present invention;
Fig. 2 is a view for explaining an appearance of a main part of an embodiment;
Fig. 3 is a front view of Fig. 2;
Fig. 4 is a cross-sectional view of Fig. 2;
5 is a view in which the second housing is separated from FIG. 2 ;
Figure 6 is a view showing a state in which a part of the drum is removed rearwardly in Figure 5;
7 is a diagram illustrating a drum and some components;
Fig. 8 is a cross-sectional view of Fig. 7;
9 is an exploded perspective view of FIG. 7;
10 is an exploded perspective view in which the main part of FIG. 7 is disassembled in detail;
11 is a view for explaining a partition wall;
12 is a view for explaining the function of the second through hole.
13 is a view for explaining a structure in which a heat exchanger is coupled to a partition wall;
14 is a view for explaining an O-ring and an O-ring cover installed on a bulkhead;
FIG. 15 is a view for explaining a state in which the configuration of FIG. 14 is coupled to other components; FIG.
16 is a view showing a rotating shaft;
17 is a view for explaining a state in which the rotation shaft of FIG. 16 is coupled to another component;
18 is a view illustrating a storage tank and a water level sensor.
19 is a view for explaining a cross section of the storage tank.
20 is a view for explaining an embodiment of the supply pipe.
21 is a view for explaining another embodiment of the supply pipe.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention that can specifically realize the above objects will be described with reference to the accompanying drawings.

In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the content throughout this specification.

1 is a view for explaining the concept of an embodiment of the present invention.

Referring to FIG. 1 , since the washing machine according to an exemplary embodiment performs various laundry treatments such as washing and rinsing using carbon dioxide, it includes components capable of storing carbon dioxide or processing carbon dioxide.

The washing machine according to an embodiment may be divided into a supply unit that supplies carbon dioxide, a laundry unit that processes clothes, and a recycling unit that processes used carbon dioxide. The supply unit may include a tank for storing liquid carbon dioxide and a compressor for liquefying gaseous carbon dioxide. The tank may include a make-up tank and a storage tank. The washing unit may include a washing chamber into which carbon dioxide and clothes may be put together. The regeneration unit includes a filter for separating contaminants dissolved in liquid carbon dioxide after washing, a cooler for converting gaseous carbon dioxide into a liquid state, a distillation chamber for separating contaminants dissolved in liquid carbon dioxide, and a storage unit for storing contaminants separated after distillation. Contamination chambers may be included.

The replenishment tank 20 may store carbon dioxide to be supplied to the washing chamber 10 . Of course, the replenishment tank 20 is a storage tank that can be used when replenishment of carbon dioxide is required, and may not be provided in a situation where replenishment of carbon dioxide is not required. In a normal situation, the replenishment tank is not provided, and the replenishment of carbon dioxide is made while the replenishment tank is coupled as necessary, and when the replenishment is completed, it is possible to separate the replenishment tank from the washing machine.

The storage tank 30 supplies carbon dioxide to the washing chamber 10 and stores the carbon dioxide recovered through the distillation chamber 50 .

The cooler 40 liquefies gaseous carbon dioxide again and stores it in the storage tank 30 .

The distillation chamber 50 distills the liquid carbon dioxide used in the washing chamber 10 . Carbon dioxide is vaporized through a distillation process to separate and remove contamination.

The compressor 80 may depressurize the pressurized interior of the washing chamber 10 to about 1.5 bar.

The contamination chamber 60 stores contaminants filtered through distillation in the distillation chamber 50 .

The filter unit 70 may filter out contaminants while discharging the liquid carbon dioxide used in the washing chamber 10 to the distillation chamber 50 . As the filter unit 70, a filter having a plurality of fine holes may be used.

In the washing chamber 10, clothes are put in and washed or rinsed. When the valve of the storage tank 30 connected to the washing chamber 10 opens the flow path, the atmospheric pressures in the washing chamber 10 and the storage tank 30 become similar. At this time, gaseous carbon dioxide may be injected first, and then, liquid carbon dioxide may be filled while pressurizing the inside of the washing chamber 10 through equipment such as a pump. In the washing chamber 10, it is possible to perform washing for 10 to 15 minutes and rinsing for 3 to 4 minutes at approximately 45 to 51 bar and 10 to 15° C. conditions. When washing or rinsing is completed, liquid carbon dioxide is discharged from the washing chamber 10 to the distillation chamber 50 .

The valve 90 removes air inside the washing chamber 10 before starting washing to prevent moisture from freezing in the washing chamber 10 . This is because, when moisture is frozen in the washing chamber 10 , washing performance is deteriorated.

FIG. 2 is a view for explaining an external appearance of a main part of an embodiment, FIG. 3 is a front view of FIG. 2 , and FIG. 4 is a cross-sectional view of FIG. 2 .

2 to 4 , the laundry chamber 10 according to an exemplary embodiment includes a door 300 , a first housing 100 , and a second housing 200 . In this case, the washing chamber 10 refers to a space in which clothes are accommodated and various clothes treatments such as washing or rinsing clothes are performed. In addition, the washing chamber may have a motor assembly provided therein that provides a driving force for rotating the drum accommodated in the washing chamber.

The door 300 may be provided on one side of the first housing 100 to open and close the inlet 102 provided in the first housing. When the door 300 opens the inlet 102 , the user can put the clothes requiring processing into the first housing 100 or take out the processed clothes.

A space is provided in the first housing 100 in which the drum 350 in which the laundry is accommodated is inserted. The drum 350 is rotatably provided so that the liquid carbon dioxide and the clothes are mixed with each other while the laundry is accommodated therein.

An opening 104 is provided in the first housing 100 in addition to the inlet 102 . The opening 100 is located on the opposite side of the inlet 102 , and is larger than the size of the inlet 102 .

The first housing 100 is generally formed in a cylindrical shape, the inlet 102 having a circular shape is formed on one side, and the opening 100 having a circular shape is provided on the other side.

The drum 350 can be rotated clockwise or counterclockwise inside the first housing 100 while forming a cylindrical shape similar to the shape of the inner space of the first housing 100 .

The size of the opening 104 may be larger than the cross-sectional size of the drum 350 so that a worker or a user can take out the drum 350 through the opening 104 and perform repair. In this case, the size of the opening 104 may be larger than the size of the maximum cross-section of the drum 350 . Accordingly, a worker or the like may open the opening 104 to take out the drum 350 . It is also possible to install the drum 350 inside the first housing 100 through the opening 104 .

The size of the opening 104 may be larger than the size of the maximum cross-section of the space of the first housing 100 . In addition, the size of the opening 104 may be kept the same up to the central portion of the first housing 100 . When an operator or the like takes out or inserts the drum 350 into the first housing 100 , a space sufficient not to interfere with the drum 350 may be secured.

In an embodiment, the input of the clothes into the first housing 100 may use the inlet 102 , and the maintenance or assembly of the drum 350 may use the opening 104 . The inlet 102 and the opening 104 may be positioned on opposite sides of the first housing 100 to face each other.

An inlet pipe 110 through which carbon dioxide is supplied to the first housing 100 is provided in the first housing 100 . The inlet pipe 110 is a pipe exposed to the outside of the first housing 100 , and a pipe through which carbon dioxide can move may be coupled to the components described in FIG. 1 .

A filter fixing part 130 capable of fixing the filter part 70 is provided in the first housing 100 . The filter fixing part 130 is formed to protrude from the cylindrical shape of the first housing 100 in a radial direction to form a space into which the filter can be inserted. The filter fixing part 130 is provided with a discharge pipe 132 through which carbon dioxide filtered through the filter part 70 can be discharged from the first housing 100 . Carbon dioxide used in the first housing 100 may be discharged to the outside of the first housing 100 through the discharge pipe 132 .

The first housing 100 includes a first flange 120 formed along the opening 104 . The first flange 120 extends in a radial direction along the outer circumferential surface of the first housing 100 similarly to the cylindrical shape of the first housing 100 . The first flange 120 is evenly disposed along the circumference of the first housing 100 in a direction in which the radius of the first housing 100 increases.

The second housing 200 may be coupled to the first housing 100 to form one washing chamber. In this case, the washing chamber may provide a space in which clothes are processed and a space in which a motor assembly providing driving force for rotating the drum is installed.

The second housing 200 includes a second flange 220 coupled to the first flange 120 . The second housing 200 is formed to have a size similar to the cross-section of the first housing 100 , and is disposed at the rear of the first housing 100 .

The second flange 220 is coupled to the first flange 120 by a plurality of bolts, so that the internal pressure is the external atmospheric pressure while the second housing 200 is fixed to the first housing 100 . Allows greater pressure to be maintained.

A filter 140 capable of filtering foreign substances is disposed in the first filter fixing part 130 provided in the first housing 200 . The filter 140 includes a plurality of small holes, so that foreign substances cannot pass through the holes, while liquid carbon dioxide passes through the holes and is discharged to the outside of the first housing 100 through the discharge pipe 132 . can

In one embodiment, the barrier rib 400 seals the opening 104 and is coupled to the first housing 100 . The second housing 200 may seal one surface of the partition wall 400 .

Referring to FIG. 4 , the drum 350 is disposed in the space on the left side of the partition wall 400 , so that laundry or rinsing can be performed while the clothes are mixed with liquid carbon dioxide. On the other hand, the motor assembly 500 is disposed in the space on the right side of the partition wall 400 to provide a driving force for rotating the drum 350 . In this case, a part of the motor assembly 500 may pass through the partition wall 400 to be coupled to the drum 350 .

The partition wall 400 is formed to be larger than the size of the opening 104 and is disposed in contact with the opening 104 to seal the opening 104 . The partition wall 400 and the opening 140 have a substantially circular shape similar to that of the first housing 100 , and the diameter L of the opening 104 is smaller than the diameter of the partition wall 400 . . The diameter L of the opening 104 is larger than the diameter of the drum 350 . Accordingly, the size of the cross section of the drum 350 is the smallest, the cross section of the opening 104 is the middle size, and the size of the partition wall 400 is the largest.

The partition wall 400 is disposed to have a plurality of steps, so that strength can be secured.

A seating groove 122 to which the partition wall 400 is coupled is formed along the opening 104 in the first flange 120 . That is, the seating groove 122 is provided at a portion extending in the radial direction from the opening 104 . The seating groove 122 is recessed by the thickness of the partition wall 400 so that the first flange 120 and the second flange 220 can contact each other. The seating groove 122 is formed to have the same shape as the outer circumferential shape of the partition wall 400, so that when the partition wall 400 is seated in the seating groove 122, the surface of the first flange 120 is It is possible to flatten out.

The first flange 120 is provided with a first seating surface 124 extending in a radial direction rather than a circumference of the seating groove 122 , and the second flange 220 has a first seating surface 124 on the first flange 220 . A second seating surface 224 coupled to the surface contact is provided. The first seating surface 124 and the second seating surface 224 are disposed to be in contact with each other, so that carbon dioxide injected into the inner space of the first housing 100 is prevented from being discharged to the outside. The first seating surface 124 and the second seating surface 224 are disposed on the outer peripheral surfaces of the first housing 100 and the second housing 200, so that the two housings are bolted to each other while making surface contact with each other. A bonding surface capable of being coupled may be provided.

A heat exchanger 600 through which a refrigerant moves is disposed in the partition wall 400 , and the heat exchanger 600 is disposed in a space formed by the first housing 100 and the partition wall 400 . The heat exchanger 600 may change the temperature of the space of the first housing 100 . It is possible to lower the humidity of the inner space of the first housing 100 by changing the temperature of the space formed by the first housing 100 to a low level.

A heat insulating member 650 is disposed between the heat exchanger 600 and the partition wall 400 . The heat insulating member 650 blocks the temperature of the heat exchanger 600 from being directly transferred to the partition wall 400 . The heat insulating member 650 reduces the effect of the temperature change of the heat exchanger 600 on the partition wall 400 . The heat insulating member 650 is formed similarly to the shape of the heat exchanger 600 , so that it is possible to cover the entire area of the heat exchanger 600 .

FIG. 5 is a view in which the second housing is separated from FIG. 2 , and FIG. 6 is a view illustrating a state in which a part of the drum is removed rearwardly in FIG. 5 .

5 and 6 , when the second housing 200 is separated into the first housing 100 , the partition wall 400 is exposed to the outside. Since the partition wall 400 is coupled to the seating groove of the first housing 100 , even if the second housing 200 is separated from the first housing 100 , the interior of the first housing 100 . The space is not exposed to the outside. The partition wall 400 is coupled to the second housing 200 by a plurality of bolts or the like.

A motor assembly 500 is coupled to the central portion of the partition wall 400 , and a second through hole 420 is formed at an upper side of the motor assembly 500 . A refrigerant pipe 610 for circulating a refrigerant through the heat exchanger 600 passes through the second through hole 420 .

When the partition wall 400 is separated from the first housing 100 , the opening 104 is exposed. At this time, the drum 350 can be withdrawn to the outside through the opening 104 . Since the size of the opening 104 is larger than that of the drum 350 , maintenance of the drum 350 is possible through the opening 104 .

A gasket 320 is disposed between the partition wall 400 and the seating groove 122 . Accordingly, when the partition wall 400 is coupled to the first housing 100 , it is possible to prevent carbon dioxide from leaking therebetween. When the partition wall 400 is seated in the seating groove 122 , it is possible to be coupled by a plurality of bolts while pressing the gasket 320 . A plurality of coupling holes for coupling to the first housing 100 may be evenly disposed along the outer circumferential surface of the partition wall 400 .

7 is a diagram illustrating a drum and some components, FIG. 8 is a cross-sectional view of FIG. 7 , FIG. 9 is an exploded perspective view of FIG. 7 , and FIG. 10 is an exploded perspective view of the main part of FIG. 7 in detail.

7 and 8 illustrate a state in which the first housing 100 is removed, the drum 350 is exposed to the outside. The drum 350 is also formed in the same shape as a cylinder as a whole, and the clothes inserted through the inlet 102 in the front are provided to be movable into the inside of the drum 350 .

The drum 350 , the heat exchanger 600 , and the heat insulating member 650 are disposed on the left side with the partition wall 400 interposed therebetween. The motor assembly 500 is disposed on the right side of the partition wall 400 .

9 is a view in which the drum 350 and the partition wall 400 are separated. A rotating shaft 510 of the motor assembly 500 is coupled to the drum 350 at the rear of the drum 350 . Accordingly, when the rotating shaft 510 is rotated, the drum 350 may also be rotated. Also, when the rotation direction of the rotation shaft 510 is changed, the rotation direction of the drum 350 is also changed.

Since the motor assembly 500 is coupled to the partition wall 400 , a driving force for rotating the drum 350 is not transmitted using a separate belt or the like. Therefore, in one embodiment, since the rotational force of the motor is directly transmitted, it is possible to reduce the loss of force or the noise generated.

FIG. 10 provides an exploded perspective view of the components installed on the partition wall in FIG. 9 .

The heat exchanger 600 is formed to have a donut shape as a whole similar to the shape of the opening 104 . A circular through hole 602 is formed in the center of the heat exchanger 600 to allow the rotation shaft 510 of the motor to pass therethrough.

The heat insulating member 650 is provided in a shape corresponding to the heat exchanger 600 , and blocks the temperature change generated in the heat exchanger 600 from being transmitted to the partition wall 400 . The heat insulating member 650 is made of a material having low temperature conductivity, and is disposed between the heat exchanger 600 and the partition wall 400 . A circular through hole 652 is formed in the center of the heat insulating member 650 to allow the rotation shaft 510 of the motor to pass therethrough.

The through-hole 602 of the heat exchanger 600 and the through-hole 652 of the heat insulating member 650 may form a circular shape having a similar size. However, the through hole 652 is additionally provided with a through hole 654 through which the refrigerant pipe 610 providing the refrigerant to the heat exchanger 600 passes.

The heat exchanger 600 includes a bracket 620 coupled to the partition wall 400 . The bracket 620 may be fixed to the partition wall 400 by a bolt 624 passing through the partition wall 400 and a cap nut 626 coupled to the bolt 624 .

The bracket 620 has a three-dimensionally stepped shape, and is disposed on a surface where the heat exchanger 600 has a thin thickness. The bolt 624 may be disposed in the stepped groove portion, and may be coupled to the cap nut 626 .

A plurality of brackets 620 are provided so that the heat exchanger 600 and the heat insulating member 650 are coupled to the partition wall 400 at a plurality of points. Although FIG. 10 provides an embodiment in which the bracket 650 is composed of three, it is possible that a larger number of brackets are disposed or a smaller number of brackets are disposed. The plurality of brackets may be evenly arranged at various positions of the heat exchanger 600 to stably fix the heat exchanger 600 .

The motor assembly 500 is coupled to the partition wall 400 . The motor assembly 500 may include a stator 570 , a rotor 550 , and a bearing housing 520 . The bearing housing 520 includes the rotating shaft 510 . One end of the rotating shaft 510 is coupled to the rotor 550 , and the other end of the rotating shaft 510 is coupled to the drum 350 . Accordingly, as the rotor 550 rotates around the stator 570 , the rotation shaft 510 also rotates.

The stator 570 is fixed to the bearing housing 520 to provide an environment in which the rotor 550 rotates.

When the bearing housing 520 is coupled to the partition wall 400 , an O-ring 450 is disposed between the bearing housing 520 and the partition wall 400 to be injected into the first housing 100 . The liquid carbon dioxide is prevented from moving into the gap between the partition wall 400 and the bearing housing 520 . At this time, an O-ring cover 460 is disposed in order to improve the coupling force of the O-ring 450 . The O-ring cover 460 is formed similarly to the shape of the O-ring 450 . The O-ring cover 460 may reduce the surface on which the O-ring 450 is exposed to one side of the partition wall 400, thereby sealing the gap more strongly.

11 is a diagram illustrating a partition wall. 11A is a view of the partition wall 400 as viewed from the front, and FIG. 11B is a side cross-sectional view of the central portion of the partition wall 400 .

Since the partition wall 400 has a plurality of steps as shown in the side cross-sectional view, the heat exchanger 600 is fixed on one side and the motor assembly 500 can be fixed on the other side. have.

A first through hole 410 through which the rotation shaft 510 of the motor passes is disposed in the center of the partition wall 400 . The first through hole 410 is formed in a circular shape, so that no contact occurs with the rotation shaft 510 passing through the first through hole 410 .

The partition wall 400 includes a second through hole 420 through which gaseous carbon dioxide moves. The second through hole 420 may be disposed at a higher position than the first through hole 410 . The second through hole 420 is disposed so that the refrigerant pipe 610 passes therethrough. The size of the second through hole 420 may be larger than the size of the first through hole 410 .

The second through hole 420 may be two separate holes. The second through hole 420 may be disposed to form a symmetry with respect to the center of the partition wall 400 .

The partition wall 400 is a part separable from the first housing 100 or the second housing 200, and provides a structure in which the heat exchanger 600 and the motor assembly 500 are coupled. can

In addition, when the partition wall 400 is separated from the first housing 100 , an environment in which a user or the like can separate the drum 350 from the first housing 100 may be provided.

The partition wall 400 is formed to be stepped forward or backward a plurality of times, and strength may be increased. In addition, by having a curved surface in some sections, it is possible to be formed to withstand forces in various directions. The outermost portion of the partition wall 400 may form a shape coupled to the seating groove 122 of the first housing 100 .

11b, while moving to the central part based on the outermost part of the partition wall 400, it is stepped by various lengths in various directions, such as protruding to the left, protruding to the right, and then protruding to the left again. can increase

12 is a view for explaining the function of the second through hole.

Carbon dioxide is injected into the drum 350 to perform washing. At this time, the carbon dioxide is a mixture of liquid carbon dioxide and gaseous carbon dioxide. Since liquid carbon dioxide is heavier than gaseous carbon dioxide, it is positioned at the bottom, and gaseous carbon dioxide is positioned in the empty space above it.

As the drum 350 is rotated, liquid carbon dioxide is mixed with clothes and the like positioned inside the drum 350 .

The partition wall 400 blocks the movement of liquid carbon dioxide injected into the space provided by the first housing 100 and the partition wall 400 into the space provided by the second housing 200 and the partition wall 400 . do. That is, since the partition wall 400 seals the opening 104 , liquid carbon dioxide cannot move to the opposite side of the partition wall 400 .

A space formed by the first housing 100 and the partition wall 400 and a space formed by the second housing 200 and the partition wall 400 are separated from each other while laundry treatment such as washing is performed. The space formed by the housing 100 and the partition wall 400 is filled with liquid carbon dioxide and gaseous carbon dioxide at a pressure higher than atmospheric pressure. Therefore, in order to stably maintain the pressure of the washing chamber, only gaseous carbon dioxide, not liquid idealized carbon, moves into the space formed by the second housing 200 and the partition wall 400 to achieve pressure equilibrium.

At this time, the gaseous carbon dioxide may pass through the partition wall 400 through the second through hole 420 provided in the partition wall 400 . However, since the second through hole 420 is disposed at a position higher than the height of the liquid carbon dioxide, the liquid carbon dioxide cannot move through the second through hole 420 .

Typically, the amount of liquid carbon dioxide used for washing or rinsing does not exceed half of the drum 350 . That is, it does not rise above the height of the rotating shaft 510 coupled to the drum 350 .

Accordingly, when the second through-hole 420 is positioned higher than the rotation shaft 510 , the liquid carbon dioxide does not move through the second through-hole 420 . However, since gaseous carbon dioxide is filled in the space by the first housing 100 and the partition wall 400, it can freely move into the space by the second housing 200 and the partition wall 400 to achieve pressure equilibrium. have.

That is, gaseous carbon dioxide and liquid carbon dioxide are mixed in a space partitioned by the first housing 100 and the partition wall 400 while laundry treatment such as washing or rinsing is performed. On the other hand, liquid carbon dioxide does not exist in the space partitioned by the second housing 200 and the partition wall 400 , but only gaseous carbon dioxide exists. Since the two spaces are in a pressure equilibrium state, there is no need for liquid carbon dioxide to exist in the space formed by the second housing 200 and the partition wall 400 , and the amount of liquid carbon dioxide can be reduced. Accordingly, the total amount of carbon dioxide used for washing or rinsing can be reduced, so that the amount of carbon dioxide used is reduced compared to the prior art. This reduces the amount of carbon dioxide that has to be reprocessed after use. Since the amount of carbon dioxide used is reduced, the capacity of the tank for storing carbon dioxide as well as the overall size of the washing machine for using carbon dioxide may be reduced. In addition, since the amount of carbon dioxide to be reprocessed after use is reduced, the time taken for washing or rinsing may also be reduced.

13 is a view illustrating a structure in which a heat exchanger is coupled to a partition wall;

13 illustrates a cross-sectional main portion of a portion where the bracket 620 is in contact with the heat exchanger 600 .

The bracket 620 may have a stepped shape, and the stepped portion may be in contact with the heat exchanger 600 to fix the heat exchanger 600 . The protruding portion is disposed to contact the heat insulating member 650 .

The bolt 624 is fixed to the protruding part, and the bolt 624 passes through the heat insulating member 650 and the partition wall 400 . A cap nut 626 may be provided on the opposite side of the bolt 624 to fix the bolt 624 . The cap nut 626 may contact the partition wall 400 at a plurality of points to secure a fixing force to the partition wall 400 .

The cap nut 626 has a rectangular parallelepiped shape as a whole, and a coupling groove is formed in a portion in contact with the partition wall 400 . A seal 627 may be disposed in the coupling groove to seal a gap when the cap nut 626 is coupled to the partition wall 400 . That is, when the cap nut 626 is coupled to the bolt 624 , the cap nut 626 is fixed while strongly pressing the bolt 624 while the sealing 627 is compressed. At this time, while the partition wall 400 is also pressed together, the hole through which the bolt 624 passes may be sealed.

A plurality of brackets 620 may be provided to fix the heat exchanger 600 at various positions. The shape of the bracket 620 may be changed when viewed from each direction, but the method in which the bracket 620 is coupled by a bolt and a cap nut is the same.

14 is a view illustrating an O-ring and an O-ring cover installed on a bulkhead, and FIG. 15 is a view illustrating a state in which the configuration of FIG. 14 is coupled to other components.

An O-ring 450 is disposed at a portion where the bearing housing 520 is coupled to the partition wall 400 . The O-ring 450 prevents liquid carbon dioxide from moving to a space opposite to the partition wall 400 .

That is, a gap should exist in the first through hole 410 of the partition wall because the rotation shaft 510 is disposed to pass therethrough. Since the rotation shaft 510 rotates, there must be a gap with the through hole 410, and the gap cannot be sealed. Therefore, the bearing housing 520 is coupled to the partition wall 400 , and the O-ring 450 seals the gap between the bearing housing 520 and the partition wall 400 , and is sealed by the O-ring 450 . It is possible to prevent carbon dioxide from moving through the gap.

An O-ring cover 460 for preventing separation of the O-ring 450 is coupled to the O-ring 450 . The O-ring cover 460 surrounds one surface of the O-ring 450 to prevent the O-ring 450 from being exposed to a space provided by the first housing 100 . Accordingly, the O-ring cover 460 may prevent the O-ring 450 from being separated by counter pressure.

16 is a view illustrating a rotation shaft, and FIG. 17 is a diagram illustrating a state in which the rotation shaft of FIG. 16 is coupled to another component.

A rotation shaft 510 having one side coupled to the drum 350 and the other side coupled to the rotor 550 is provided at the center of the bearing housing 520 . The rotation shaft 510 is disposed to pass through the center of the bearing housing 520 .

The rotation shaft 510 may be supported by the bearing housing 520 by a first bearing 521 and a second bearing 522 . The rotating shaft 510 is supported so as to be rotatable by two bearings. In this case, the two bearings may have various shapes as long as they are rotatably supported components.

Meanwhile, since the first bearing 521 and the second bearing 522 have different sizes, the rotation shaft 510 may be stably supported. On the other hand, the shape of the rotation shaft 510 of the portion supported by each bearing may be formed differently.

A sealing part 540 is provided at one side of the first bearing 521 . The sealing part 540 is disposed along the circumference of the rotation shaft 510 . The sealing part 540 is disposed to be exposed to the space provided by the first housing 100 and the partition wall 400 so that carbon dioxide moves into the gap between the rotation shaft 510 and the bearing housing 520 . can be prevented In particular, the sealing part 540 may prevent the liquid carbon dioxide from moving to the space opposite to the partition wall 400 .

The sealing part 540 includes a shaft seal housing 542 disposed between the rotation shaft 510 and a hole through which the rotation shaft passes to seal the gap. A shaft seal 544 may be disposed at a portion where the shaft seal housing 542 and the rotation shaft 510 meet to improve sealing force. The shaft chamber 544 may be disposed to surround the outer circumferential surface of the rotation shaft 510 .

A communication hole 526 through which external air can be introduced or discharged is formed in the bearing housing 520 . The communication hole 526 of the bearing housing 520 is exposed in a space partitioned by the second housing 200 and the partition wall 400 .

A first flow path 512 and a second flow path 514 through which air can be introduced or discharged are formed in the rotation shaft 510 to be spaced apart from each other. In this case, the first flow path 512 and the second flow path 514 may be formed in a radial direction from the center of the rotation shaft 510 .

Through the first flow path 512 and the second flow path 514 , air in the space defined by the second housing 200 and the partition wall 400 can move into the rotation shaft 510 . .

In particular, a connection passage 516 connecting the first passage 512 and the second passage 514 is formed. The connection flow path 516 may be disposed at the rotation center of the rotation shaft 510 and may be vertically connected to the first flow path 512 and the second flow path 514 , respectively.

If there is no connection flow path 516 , the first flow path 512 and the second flow path 514 form a flow path in which a hole is formed in the outer surface of the rotation shaft 510 , but the opposite side thereof is blocked. Therefore, it is substantially difficult for air to move into the first flow path 512 or the second flow path 514 . To this end, in one embodiment, the connection flow path 516 connecting the two flow paths is formed, so that when the internal pressure is changed, air can more easily flow through the first flow path 512 , the second flow path 514 and By moving to the connection flow path 516, the rotation shaft 510 may be maintained the same as the external pressure change.

The rotating shaft 510 rotates in a state in which one side is fixed to the drum 350 and the other side is fixed to the rotor 550 . Therefore, noise or vibration may occur in the rotation shaft 510, and when the rotation shaft 510 rotates in a place where there is a pressure deviation, the noise or vibration is inevitably increased. Accordingly, in the present embodiment, a communication hole 526 through which air can be introduced into the bearing housing 520 is provided. Since the bearing housing 520 is a relatively large component and has a space in which air can enter and circulate, air can be introduced without distinguishing between an air inlet and an outlet. On the other hand, the rotation shaft 510 is made of a material with high rigidity, and since the strength is weak to secure a space for air to easily enter therein, the air flow path cannot be formed large. Accordingly, a plurality of flow paths are connected to each other to provide a path through which the introduced air can be discharged through the opposite flow path.

In one embodiment, the washing chamber 10 forms a closed space by combining the first housing 100 and the second housing 200 . In this case, the enclosed space may be divided into two spaces by the partition wall 400 . Based on the partition wall 400, one side may be a space for processing clothes, and the other side may be divided into a space for installing a motor or the like.

18 is a view illustrating a storage tank and a water level sensor.

Referring to FIG. 18 , the storage tank 30 in which the liquid carbon dioxide and the gaseous carbon dioxide are stored together is provided with a level sensor 301 capable of measuring the height at which the liquid carbon dioxide is stored in the storage tank 30 , that is, the water level. The water level sensor 301 is installed in the pipe 302 penetrating the inside of the storage tank 30 , so that it is possible to sense the height of the liquid carbon dioxide stored in the storage tank 30 . That is, both ends of the pipe 302 are connected to the storage tank 30 so that the water level of the pipe 302 is maintained to be the same as the water level of the storage tank 30 , and the liquid carbon dioxide in the water level sensor 301 is height can be checked. Of course, it is also possible to sense the height of the stored liquid carbon dioxide using another type of water level sensor 301 .

A supply pipe 31 , which guides liquid carbon dioxide to the storage tank 30 , is disposed at a lower portion of the storage tank 30 to pass through the storage tank 30 . The supply pipe 30 guides the liquid carbon dioxide liquefied through the distillation chamber 50 and the cooler 40 to move into the storage tank.

19 is a view illustrating a cross section of a storage tank. Referring to FIG. 19 , the storage tank 30 includes a case 31a forming an exterior, and a discharge port 32 disposed higher than the height of the liquid carbon dioxide stored in the case 31a, the case 31a) and a supply pipe 31 for supplying liquid carbon dioxide to the furnace. The case 31a is made of a metal material and forms a pressure-resistant container in which the liquid carbon dioxide stored therein can maintain a high pressure.

The storage tank 30 has a cylindrical shape and is installed so that a circular surface is disposed on the side surface. That is, the storage tank 30 is installed in the washing machine in the form of a cylinder lying on its side. Accordingly, the liquid carbon dioxide stored in the storage tank 30 is filled from the bottom with reference to FIG. 19 , and the water level increases upward as the storage amount increases.

The supply pipe 30 is disposed to penetrate the bottom of the case 30a. The supply pipe 30 includes a portion 33 passing through the storage tank 30 . At this time, the portion 33 penetrating the storage tank 30 penetrates the bottom of the storage tank 30 . The penetrating portion 33 is welded to and coupled to the storage tank 30 , so that leakage of liquid carbon dioxide between the portion 33 and the storage tank 30 can be prevented. The supply pipe 31 may extend in a vertical direction from the portion 33 . That is, it is possible that a part of the supply pipe 31 and the part 33 are always submerged in the liquid carbon dioxide stored in the storage tank 30 .

The supply pipe 31 may extend higher than the maximum height at which liquid carbon dioxide is stored from the bottom of the case 31a. The storage tank 30 is designed to withstand the pressure at which liquid carbon dioxide can be stably stored. Accordingly, the amount of liquid carbon dioxide that the storage tank 30 can store is determined, and the maximum level of such liquid carbon dioxide is also determined. Accordingly, the supply pipe is configured to extend above the maximum water level. A discharge port 32 is provided at the end of the supply pipe 31 , and the discharge port 32 is disposed higher than the maximum water level. Liquid carbon dioxide guided to the storage tank 30 is ejected into the storage tank 30 through the discharge port 32 .

The discharge port 32 is disposed to have a gap G1 from the ceiling of the storage tank. Accordingly, after the liquid carbon dioxide moving through the discharge port 32 rises to the discharge port 32 , it may be guided into the storage tank 30 .

Since the discharge port 32 is disposed higher than the maximum level of the liquid carbon dioxide, the liquid carbon dioxide supplied through the discharge port 32 does not create a wave that causes the level of the liquid carbon dioxide stored in the storage tank 30 to fluctuate. . Accordingly, since the liquid carbon dioxide flowing down through the discharge port 32 only gradually increases the level of the stored liquid carbon dioxide, it is possible to accurately measure the water level by the water level sensor 301 .

On the other hand, the carbon dioxide supplied through the discharge port 32 flows down along the inner wall of the case 31a, it is possible to be mixed with the stored liquid carbon dioxide. Even in this case, since fluctuations that periodically shake the already stored liquid carbon dioxide do not occur, an error in which the water level of the liquid carbon dioxide stored in the water level sensor 301 periodically rises and falls can be prevented.

The storage tank 30 includes a pipe 37 through which gaseous carbon dioxide is supplied or discharged through the storage tank 30 , and the pipe 37 passes through a side surface of the storage tank 30 . (39).

A portion 39 through which the pipe 37 passes through the storage tank 30 is lower than the ceiling of the storage tank 30 . The penetrating portion 39 should protrude to the outside of the storage tank 30 , and since the pipe 37 does not penetrate the ceiling of the storage tank 30 , the pipe 37 causes the storage tank There is no need to make the part protruding upwards of (30). Therefore, in the present embodiment, there is no need to provide a space outside the storage tank 30 in which the structure provided higher than the storage tank 30 is disposed, so that the overall size of the washing machine including the storage tank can be reduced. have.

Meanwhile, the portion 39 through which the pipe 37 passes through the storage tank 30 may be disposed higher than the middle of the storage tank 30 . The storage tank 30 is disposed in a cylindrical shape as a whole, and since the middle height part is the widest, when the part 39 is disposed in the middle, the width of the space in which the storage tank is disposed should be Therefore, if it is disposed at a higher position than the middle, the length of the width of the storage tank that needs to be increased is reduced, so that the washing machine can be installed in a compact space in a narrower space.

The through hole 38 of the pipe 37 is disposed higher than the maximum height of the liquid carbon dioxide that can be stored in the storage tank 30 . Gas carbon dioxide may be guided to the storage tank 30 through the through hole 38 , or gaseous carbon dioxide may be discharged from the storage tank 30 . Accordingly, when the through hole 38 is submerged below the water level of the liquid carbon dioxide stored in the storage tank 30 , the gaseous carbon dioxide cannot move. In the present embodiment, the through hole 38 is disposed not to be submerged in liquid carbon dioxide, so that a movement path of gaseous carbon dioxide moving in the storage tank 30 can be secured.

Meanwhile, the pipe 37 extends upward from the penetrating portion 39 so that the through hole 38 is disposed higher than the maximum water level. At this time, the through hole 38 is disposed to have a gap G2 from the ceiling of the storage tank 30 , so that gaseous carbon dioxide may be guided to the through hole 38 .

The penetrating portion 39 is disposed at a lower position than the through hole 38 , so that a part of the pipe 37 may be submerged in liquid carbon dioxide.

20 is a view for explaining an embodiment of the supply pipe. 20a, b, and c are views showing the cross-section of the same high-grade tube cut in various directions. The supply pipe shown in FIG. 20 corresponds to a part of the supply pipe, so it is possible to mean an intermediate position of the supply pipe, or it can be interpreted as representing the entire supply pipe.

Referring to FIG. 20 , the supply pipe 31 may have a plurality of baffles 34 and 35 disposed therein. The baffles 34 and 35 are formed to protrude into the supply pipe 31 . The supply pipe 31 has a circular cross section, and the baffles 34 and 35 may be formed in a semicircular shape. In this case, the baffle may include a first baffle 34 and a second baffle 35 that are alternately disposed. The two baffles are disposed at different heights, and are disposed to face each other to generate resistance to liquid carbon dioxide moving inside the supply pipe 31 . Accordingly, it is possible to reduce a sudden change in the speed of the liquid carbon dioxide that may be generated due to a sudden change in pressure, thereby attenuating the high pressure of the liquid carbon dioxide discharged through the discharge port 37 . That is, the movement path of liquid carbon dioxide moving inside becomes longer.

That is, by forming a baffle inside the supply pipe inserted into the storage tank to reduce the flow rate and noise of liquid carbon dioxide flowing into the storage tank, the liquid oil level can be more stably controlled.

21 is a view for explaining another embodiment of the supply pipe. 21A is a view showing the upper end of the supply pipe, and FIG. 21B is a cutaway view of the center of FIG. 21A.

Referring to FIG. 21 , a cover 36 having a plurality of holes 361 formed therein is provided at the discharge port 32 . The cover 36 prevents the discharge port 32 from being exposed to the storage tank 30 as it is, and allows liquid carbon dioxide to be discharged through the plurality of holes 361 .

Therefore, it is a function similar to the baffle described in one embodiment to prevent liquid carbon dioxide from being injected into the storage tank 30 in a short time, thereby preventing the water level from fluctuating by the liquid carbon dioxide supplied into the storage tank 30. can Accordingly, the change in the level of the liquid carbon dioxide measured by the water level sensor 301 may be reduced, and thus the reliability of the measured level value may be improved.

That is, the through hole 38 of the storage tank 30 of the pipe inserted into the storage tank 30 has a structure with pores, so that liquid carbon dioxide is ejected into the pores at the outlet point to disperse the fluid energy. Therefore, since the liquid carbon dioxide flows down along the inner surface of the storage tank 30, the oil level excitation force is reduced, so that the oil level fluctuation can be reduced.

The present invention is not limited to the above-described embodiments, and as can be seen from the appended claims, modifications can be made by those skilled in the art to which the present invention pertains, and such modifications are within the scope of the present invention.

100: first housing 104: opening
120: first flange 200: second housing
220: second flange 300: door
350: drum 400: bulkhead
410: first through hole 420: second through hole
500: motor assembly 510: rotation shaft
520: bearing assembly 600: heat exchanger
650: insulation member

Claims (13)

a first housing having an opening formed therein and a space in which a drum containing laundry is inserted;
a second housing coupled to the first housing; and
Including; a storage tank for storing carbon dioxide supplied to the drum;
Carbon dioxide is injected into the drum to perform washing,
The storage tank is
A case forming an appearance, and
The discharge port is arranged higher than the height of the liquid carbon dioxide stored in the case, supplying the liquid carbon dioxide to the case A washing machine with a supply pipe. According to claim 1,
The washing machine further comprising a water level sensor for measuring the height of the liquid carbon dioxide stored in the case. According to claim 1,
The storage tank has a cylindrical shape, and is installed so that a circular surface is disposed on a side surface of the washing machine. According to claim 1,
The supply pipe is a washing machine, characterized in that it is disposed through the bottom of the case. 5. The method of claim 4,
The supply pipe is a washing machine, characterized in that it extends higher than the maximum height at which liquid carbon dioxide is stored from the bottom of the case. According to claim 1,
The supply pipe is a washing machine, characterized in that a plurality of baffles are disposed therein. 7. The method of claim 6,
The baffles are formed in a semicircular shape and are alternately arranged, so that a movement path of liquid carbon dioxide moving therein is lengthened. According to claim 1,
The washing machine, characterized in that the discharge port is provided with a cover having a plurality of holes formed therein. According to claim 1,
The storage tank is
and a pipe through which gaseous carbon dioxide is supplied or discharged through the storage tank,
The pipe is a washing machine, characterized in that through the side of the storage tank. 10. The method of claim 9,
A portion through which the pipe passes through the storage tank is lower than the ceiling of the storage tank and higher than the middle. 10. The method of claim 9,
The through-hole of the pipe is disposed higher than the maximum height of the liquid carbon dioxide that can be stored in the storage tank. According to claim 1,
It further includes a partition wall that seals the opening and is coupled to the first housing,
The second housing is a washing machine, characterized in that it seals one surface of the partition wall. 13. The method of claim 12,
wherein the partition wall blocks movement of liquid carbon dioxide injected into the space provided by the first housing and the partition wall into the space provided by the second housing and the partition wall.

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