Clothes treatment apparatus and method for controlling clothes treatment apparatus

Abstract

The present invention relates to a clothes treatment apparatus comprising: a hanger frame disposed in the width direction or the front-rear direction inside an accommodation space; a plurality of hanger parts seated on the hanger frame so as to rotate back and forth at a fixed position; a connecting part for connecting respective one sides of all of the plurality of hanger parts; a driving part disposed above an inner case so as to provide power for moving the connecting part; and a power transmission part, which penetrates the upper surface of the inner case so as to connect the driving part and the connecting part, wherein the hanger frame is coupled to the upper surface of the inner case such that the position thereof is fixed even if the driving part is driven, and the connecting part includes a moving hanger, which moves back and forth in the extension direction of the hanger frame between both ends of the hanger frame.

Description

Clothing processing device and control method of clothing processing device

[0001] The present invention relates to a garment processing device and a control method thereof. More specifically, it relates to a garment processing device and a control method thereof capable of performing refresh operations such as sterilization, wrinkle removal, deodorization, and drying of garments by supplying steam and hot air to the garments.

[0002] A garment processing device refers to a device developed for washing and drying clothes and removing wrinkles from clothes in homes and laundries. The concept of a garment processing device includes washing machines for washing clothes, dryers for drying clothes, washer-dryers that have both washing and drying functions, garment care machines for refreshing clothes, and steamers for removing wrinkles from clothes.

[0003] Meanwhile, a garment processing device has emerged that functions as a garment care system, enabling clothes to be kept fresh and clean without the need to soak them in water or wash them with detergent.

[0004] Among such conventional clothing processing devices, a clothing processing device has emerged that performs a refresh process by supplying either high-temperature air or steam to the clothing to deodorize the clothing, dry the clothing, and remove wrinkles from the clothing.

[0005] The garment processing device capable of performing the above refresh procedure could be configured to allow the garment to be heated while supplying hot air or steam to the garment in order to remove fine dust or foreign substances attached to the garment. (Refer to Chinese Utility Model Publication No. 205368824)

[0006] The garment processing device is configured to place garments on a plurality of hangers extending in the height direction within a receiving space, and to connect the plurality of hangers with a connecting part such as a link, thereby reciprocating the link to reciprocate and rotate all of the plurality of hangers simultaneously. The garment processing device has the advantage that vibrations caused by shaking of the garments can be minimized as the plurality of hangers reciprocate and rotate at a fixed position, and the maximum output of the drive unit can be utilized by rotating the link through a rotating shaft that rotates continuously in one direction.

[0007] However, this garment processing device is equipped with a structure in which multiple hanger sections for holding garments are arranged vertically and fixed by penetrating the upper surface of an inner case that forms a receiving space for the garments, with the garments mounted on the lower part. Due to the structure of these hanger sections, a connecting section must be provided to connect the area between the upper and lower parts of the hanger sections to minimize twisting of the hanger sections and enable stable reciprocating rotation. However, since the multiple hanger sections are arranged with complete spacing between them and it is difficult to secure a structure that can be combined with the connecting section except for the upper part, there was a structural limitation in that the connecting section had to be provided to connect the upper part of the hanger section from outside the receiving space.

[0008] As a result, the garment processing device had a fundamental problem in that it could not utilize the maximum output of the drive unit because it could not reciprocate the connecting unit at a frequency higher than a specific frequency in order to stably reciprocate multiple hanger units.

[0009] Recently, a garment processing device has appeared in which the connecting part and the hanger part can be placed inside the receiving space. (See Japanese Patent Publication No. 214889B2)

[0010] The garment processing device is configured such that a width-direction support plate supporting the hanger unit is placed inside the receiving space, and a connecting unit is positioned on the upper part of the support plate to connect the lower part of the hanger unit. Additionally, a drive unit is mounted on the support plate and placed within the receiving space to reciprocate the connecting unit. As a result, the drive unit can be directly connected to the connecting unit, which has the advantage of transmitting the output of the drive unit to the connecting unit without loss.

[0011] However, the garment processing device had a structural limitation in that the connection part, hanger part, and drive part were all positioned on the upper part of the support plate, making it impossible to install a power conversion structure that converts the rotational motion generated by the drive part into reciprocating motion and transmits it to the connection part.

[0012] Accordingly, the clothing processing device had a fundamental problem in that, in order to reciprocate the connecting part, the driving unit had to repeat the process of rotating the shaft in one direction and stopping, then rotating it in another direction and stopping, so the driving unit could not rotate the shaft at maximum output and consumed a lot of energy.

[0013] Furthermore, since the connection part of the garment processing device is directly exposed to the receiving space, there was a risk that components such as hangers mounted on the hanger section would be rubbed against or damaged by the connection part, and there was also a possibility that the connection part could be damaged by interference with the garment.

[0014] In addition, the garment processing device had a problem in that not only the connection parts but also the drive parts were directly exposed to foreign substances discharged from the garments, as well as steam and hot air supplied from the machine room, which could cause safety accidents.

[0015] Meanwhile, there has also been a garment processing device in the past in which the hanger unit itself is provided in a bar type, which is free from the problems of the aforementioned prior art, allowing multiple garments to be mounted at once and the entire hanger unit to be moved back and forth. (Refer to Korean Registered Patent Publication No. KR101608655) This garment processing device is equipped with a hanger unit that can mount garments by being provided in a bar shape extending in the width direction within a receiving space, and is configured to move the mounted garments back and forth in the width direction while shaking the hanger unit left and right; thus, the connecting part itself can be omitted, which has the advantage of not causing the aforementioned problems.

[0016] However, this garment processing device generated significant vibration as the clothes mounted on the hanger moved back and forth, and there was a problem in that the vibration energy increased as the number of mounted clothes increased. Consequently, this garment processing device had a problem in that the vibration energy and noise increased as the hanger was shaken faster, making it impossible to shake the hanger beyond a certain level.

[0017] The present invention aims to solve the problem of providing a garment processing device comprising a moving hanger capable of stably reciprocating rotation by connecting a plurality of hanger units that hold garments within a receiving space within the receiving space.

[0018] The present invention aims to solve the problem of providing a garment processing device capable of shaking the garment while the driving unit continuously generates rotational motion by providing a motion conversion unit capable of converting rotational motion generated in the driving unit into reciprocating motion and transmitting it to the connecting unit.

[0019] The present invention aims to solve the problem of providing a clothing processing device capable of ensuring stability by placing the driving unit and the motion conversion unit outside the receiving space.

[0020] The present invention aims to solve the problem of providing a garment processing device that prevents the connecting part and the hanger part from rubbing against the garment or the garment from interfering with the connecting part and the hanger part, even if the connecting part and the hanger part are placed inside a receiving space.

[0021] The present invention aims to solve the problem of providing a clothing processing device capable of blocking exposure to steam or hot air even if the connecting part and the motion transmission part that transmits power from the motion conversion part to the connecting part are exposed to the receiving space.

[0022] To solve the above-mentioned problem, the present invention provides a garment processing device comprising a hanger frame extending in the width direction within a receiving space and a driving unit positioned outside the receiving space, a hanger unit for holding a clothes hanger or garment at the upper part of the hanger frame, and a hanger unit that receives power from the driving unit and reciprocates, all positioned within the receiving space.

[0023] That is, the above connecting part does not rotate the hanger part on which the clothing is mounted through a separate additional member, but rather both the connecting part and the hanger part that directly supports the clothing are positioned close together inside the receiving space (21).

[0024] Thus, the connecting part is directly coupled to the hanger part that holds the clothing, allowing it to reciprocate.

[0025] In other words, the connecting part is not positioned above the inner case, but can be positioned at a location where it overlaps in height with the hanger part positioned inside the receiving space.

[0026] Thus, the connecting part can stably reciprocate all hangers simultaneously, even if multiple hangers are arranged or if a greater load of clothing is applied to each hanger.

[0027] As a result, the moving hanger of the present invention can stably shake all the clothes even when more clothes are mounted than in conventional clothing processing devices, thereby allowing the number of hanger units to be further expanded.

[0028] The above hanger frame can be fixed so as not to move inside the inner case. Therefore, even if multiple hanger sections are provided to reciprocate the clothing, vibration or noise generation can be minimized.

[0029] To solve the above-mentioned problem, the clothing processing device of the present invention may include a cabinet, an inner case providing a receiving space in which clothing is placed inside the cabinet, a machine room supplying one or more of steam and air to the receiving space, and a moving hanger provided to place the clothing inside the receiving space and shake the clothing.

[0030] The above moving hanger may include a hanger frame comprising a support body arranged in the width direction or the front-rear direction of the inner case, a plurality of hanger sections arranged along the extension direction of the support body for mounting the clothing, a connecting section provided to connect all of the plurality of hanger sections, a driving section provided to rotate an eccentric shaft rotating along a certain radius in one direction, a motion conversion section connected to the eccentric shaft to convert the rotational motion of the eccentric shaft into reciprocating motion, and a motion transmission section coupled to or extended from the motion conversion section to reciprocate the connecting section.

[0031] The support body, the hanger part, and the connecting part may be disposed inside the receiving space.

[0032] The above driving unit may be placed outside the above receiving space.

[0033] The above motion conversion unit may have at least a portion disposed outside the receiving space.

[0034] At least a portion of the above motion transmission unit may be positioned inside the above receiving space.

[0035] The above motion transmission unit and the above motion conversion unit can be formed as a single unit.

[0036] The above hanger frame includes an extension body that extends from both ends of the support body and fixes the support body to the upper surface of the inner case, and at least a portion of the extension body may be disposed inside the receiving space.

[0037] The support body and the extension body can be formed integrally.

[0038] The garment processing device of the present invention may further include a support frame coupled to the upper part of the inner case and supporting the moving hanger.

[0039] The support body, the hanger part, and the connecting part may be positioned below the support frame.

[0040] At least a portion of the motion conversion unit and the driving unit may be positioned above the support frame.

[0041] The above motion transmission unit may include a transmission shaft that passes through the support frame and transmits the power transmitted to the motion conversion unit to the connection unit.

[0042] The above moving hanger may further include a transmission bearing coupled to the support frame and rotatably supporting the transmission shaft.

[0043] The above transmission shaft may further include a seating ring that protrudes from or is coupled to the outer surface and is seated on the transmission bearing.

[0044] The above-mentioned hanger part can be seated on the upper part of the above-mentioned support body and arranged to be reciprocally rotatable.

[0045] The above connecting part may be positioned at a location lower than the upper surface of the hanger part and higher than the upper surface of the hanger frame.

[0046] The above-described hanger portion may include a hanger body to which a clothes hanger portion on which the garment is mounted is detachably fixed, and a hanger shaft extending from the lower part of the hanger body and seated on the hanger frame.

[0047] The above connecting part may be connected to one side of the hanger body or the hanger shaft.

[0048] To solve the above-mentioned problem, the garment processing device of the present invention may include: a driving unit configured to rotate an eccentric shaft rotating along a certain radius in one direction; a motion conversion unit connected to the eccentric shaft to convert the rotational motion of the eccentric shaft into reciprocating motion; and a motion transmission unit coupled to or extended from the motion conversion unit to reciprocate the connecting unit.

[0049] The above-described hanger part includes a mounting groove on the upper part in which a hook of a clothes hanger on which the garment is mounted is detachably seated, the driving part and the motion transmission part are positioned above the mounting groove, and the connecting part can be connected to the hanger part below the mounting groove.

[0050] The above-mentioned seating groove is provided to extend in the diameter direction of the hanger portion and be convex upward, and the above-mentioned connecting portion may be positioned below the lowest end of the seating groove.

[0051] The support body may be positioned below the hanger portion, and the connecting portion may be positioned below the seating groove and above the support body.

[0052] The moving hanger comprises a hanger frame including a support body arranged in the width direction or the front-rear direction of the inner case, a plurality of hanger sections arranged along the extension direction of the support body for mounting the garment, a connecting section provided to connect all of the plurality of hanger sections, a driving section including a drive shaft that rotates in one direction, a motion conversion section including an extension shaft provided to receive power from the drive shaft and reciprocate, and a motion transmission section coupled to or extended by the extension shaft and provided to reciprocate the connecting section.

[0053] The support body, the hanger part, and the connecting part may be disposed inside the receiving space.

[0054] The present invention has the effect of stably reciprocating a plurality of hanger units that hold clothing within a receiving space by connecting them within the receiving space.

[0055] The present invention has the effect of utilizing the maximum output of the driving unit that reciprocates the connecting part.

[0056] The present invention has the effect of ensuring stability by placing the driving unit and the motion conversion unit outside the receiving space.

[0057] The present invention has the effect of preventing the connecting part and the hanger part from rubbing against the clothing or the clothing from interfering with the connecting part and the hanger part, even if the connecting part and the hanger part are placed inside the receiving space.

[0058] The present invention has the effect of preventing exposure to steam or hot air even if the connecting part and the motion transmission part that transmits power from the motion conversion part to the connecting part are exposed to the receiving space.

[0059] The present invention has the effect of being able to hold six or more garments at once.

[0060] The present invention has the effect of being able to rotate six or more garments simultaneously.

[0061] The present invention has the effect of stably rotating mounted clothing at the maximum output of the motor while minimizing noise and vibration generation.

[0062] FIG. 1 illustrates the exterior of the clothing processing device of the present invention.

[0063] Figure 2 illustrates the upper structure of the inner case.

[0064] FIG. 3 illustrates the operation of the moving hanger of the present invention.

[0065] FIG. 4 illustrates an embodiment of the structure of the moving hanger of the present invention.

[0066] FIG. 5 illustrates an embodiment in which the above-mentioned hanger part can be installed.

[0067] FIG. 6 illustrates an embodiment in which the above-mentioned hanger part can be rotated.

[0068] FIG. 7 illustrates an example of the structure of the above-mentioned hanger part.

[0069] FIG. 8 illustrates an embodiment in which the above-mentioned hanger unit reciprocates.

[0070] FIG. 9 illustrates a configuration for shielding the above-mentioned hanger frame.

[0071] FIG. 10 illustrates a detailed structural embodiment of the shielding part.

[0072] FIG. 11 illustrates the operation process of the hanger unit with the shielding unit installed.

[0073] FIG. 12 illustrates the internal state of the shielding part.

[0074] FIG. 13 illustrates another embodiment of the driving unit of the moving hanger of the present invention.

[0075] FIG. 14 illustrates the structure of the drive unit shown in FIG. 13.

[0076] FIG. 15 illustrates the internal configuration of the driving unit and displacement generating unit shown in FIG. 13.

[0077] FIG. 16 illustrates the operating principle of the moving hanger shown in FIG. 13.

[0078] FIG. 17 illustrates the operation method of the power transmission unit shown in FIG. 13.

[0079] FIG. 18 illustrates an example of the detailed structure of the moving hanger shown in FIG. 15.

[0080] FIG. 19 illustrates another embodiment of the driving unit of the moving hanger of the present invention.

[0081] FIG. 20 illustrates the detailed structure of the drive unit shown in FIG. 19.

[0082] FIG. 21 illustrates an embodiment of the displacement generating unit illustrated in FIG. 19.

[0083] FIG. 22 illustrates another embodiment of the moving hanger drive unit of the present invention.

[0084] FIG. 23 illustrates the operating principle of the moving hanger of FIG. 22.

[0085] FIG. 24 illustrates the operation process of the moving hanger of FIG. 22.

[0086]

[0087] Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the attached drawings. In this specification, identical or similar reference numbers are assigned to identical or similar components even if they are different embodiments, and the description thereof is replaced by the first description. Singular expressions used in this specification include plural expressions unless the context clearly indicates otherwise. Furthermore, in describing the embodiments disclosed in this specification, detailed descriptions of related prior art are omitted if it is determined that such detailed descriptions may obscure the essence of the embodiments disclosed in this specification. Additionally, it should be noted that the attached drawings are intended only to facilitate understanding of the embodiments disclosed in this specification, and should not be interpreted as limiting the technical concept disclosed in this specification.

[0088] FIG. 1 illustrates the exterior of the clothing processing device (1) of the present invention.

[0089] Referring to FIG. 1(a), the clothing processing device of the present invention may include a cabinet (100) forming an exterior and a door (11) rotatably coupled to the cabinet (10).

[0090] The cabinet (100) may be provided with a height that is longer than the width in the left-right direction and the width in the front-back direction. As a result, clothing can be placed inside the cabinet (100) without being folded.

[0091] Referring to FIG. 1(b), an inner case (20) having a receiving space (21) for receiving clothing may be provided inside the cabinet (10). The inner case (20) may be provided with an opening at the front for the clothing to enter and exit, and the opening may be covered by the door (11).

[0092] The inner case (20) may be provided with a plastic resin series and may be provided with a reinforced plastic resin series that is not deformed by air at a temperature higher than room temperature air or heated air (hereinafter, hot air) and steam or moisture.

[0093] The inner case (20) may be provided with a height greater than its width. Thus, the clothing can be accommodated in the receiving space (21) without being folded or wrinkled.

[0094] The clothing processing device (1) of the present invention may include a clothes hanger part (1000) capable of holding clothing in the receiving space (21) of the inner case (20).

[0095] The above-mentioned clothes hanger part (1000) can be placed on the upper part of the above-mentioned inner case (20) and can be seated on a moving hanger (100) that holds clothing. The above-mentioned clothes hanger part (1000) can be detachably provided on the moving hanger (100).

[0096] When the clothing is mounted on the moving hanger (100), the clothing can be positioned in a floating state within the receiving space (21).

[0097] The clothing processing device of the present invention may further include a pressure member (50) that is coupled to the inner surface of the door (11) and can fix the clothing.

[0098] The above-mentioned pressure member (50) may include a pressure surface (522) disposed on the inner surface of the door (11) and a pressure panel (521) rotatably coupled to the pressure surface (522) to apply pressure to clothing disposed on the pressure surface (522). The above-mentioned pressure member (50) may apply pressure to long clothing, such as bottoms, to remove wrinkles and create an intended crease.

[0099] The clothing processing device of the present invention may be equipped with a machine room (30) in which various devices capable of supplying one or more of hot air or steam to the receiving space (21), or purifying or dehumidifying the outside air of the cabinet (10) are installed.

[0100] The machine room (30) may be separated from or partitioned from the inner case (20), but may be provided to communicate with the inner case (20).

[0101] The machine room (30) can be positioned at the bottom of the inner case (20). Thus, when hot air and steam with low specific gravity are supplied to the inner case (20), the hot air and steam can naturally be supplied to the clothing.

[0102] The machine room (30) may include a circulation duct that circulates air inside the inner case (20), and a plurality of heat exchangers disposed on the circulation duct that cool and condense the air and heat the air.

[0103] The machine room (30) may be equipped with a heat pump system that includes a compressor capable of compressing a refrigerant connected to the plurality of heat exchangers to cool or heat the air.

[0104] Meanwhile, the machine room (30) may also be equipped with a steam supply unit capable of supplying steam inside the inner case (20).

[0105] The steam supply unit described above may be configured to generate steam by heating water. As a result, the clothing contained within the inner case is exposed to hot air and steam, allowing for deodorization, sterilization, and wrinkle removal.

[0106] In front of the machine room (30), there may be a water tank (31) that supplies water for generating steam and a drainage tank (32) that collects water condensed in the circulation duct.

[0107] The water tank (31) and drainage tank (32) may be detachably provided in front of the machine room (30). Thus, even if the clothing processing device of the present invention is not placed near a water source or sewer, the user can detach and transport the water tank (31) and drainage tank (32) whenever necessary.

[0108] The water tank (31) and the drainage tank (32) can be arranged side by side along the width direction of the machine room (30).

[0109] Additionally, the machine room (30) may further include a drawer (33) for accommodating items necessary for managing the clothing. The drawer (33) may be provided to be easily pulled out of the machine room (30) and may have a space inside for accommodating items such as an iron.

[0110] A mounting base (60) on which a separate shelf can be mounted may be provided inside the inner case (20). The mounting base (60) may be provided protruding at the same height on both sides of the inner case (20).

[0111] The above-mentioned mounting base (60) may be equipped with a light-emitting part that irradiates light into the interior of the inner case (20), and the light-emitting part is configured to irradiate light toward the inner surface of the inner case (20) to prevent glare.

[0112] The above moving hanger (100) may be provided to shake the clothes hanger part (1000) to remove foreign substances and dust, etc., from the clothes mounted on the clothes hanger part (1000).

[0113] The moving hanger (100) is configured to operate when one or more of hot air and steam are supplied to the garment, thereby inducing foreign substances attached to the garment to be separated by the hot air or steam.

[0114] The above moving hanger (100) may be configured to move the above clothes hanger part (1000) back and forth.

[0115] FIG. 2 illustrates an example of a moving hanger of the clothing processing device of the present invention.

[0116] The moving hanger (100) of the clothing processing device of the present invention may include a hanger part (600) on which clothing or a clothes hanger part (1000) on which clothing is mounted is mounted, and a connecting part (500) that moves the hanger part (600) back and forth.

[0117] The above-mentioned hanger unit (600) may be provided in multiple units and may be spaced apart from each other. Thus, the above-mentioned hanger unit (600) can hold multiple garments inside the receiving space (21).

[0118] A plurality of the above-mentioned hanger sections (600) may be arranged in either the width direction or the front-rear direction of the inner case (20). Clothing or a hanger section (1000) may be mounted on the above-mentioned hanger section (600) exposed inside the receiving space (21).

[0119] Regardless of whether the hanger part (600) is provided to be mounted on the upper or lower part, the load of the clothing as well as the load of the hanger part (600) can be concentrated on the lower part of the hanger part (600).

[0120] The connecting part (500) may be provided inside the receiving space (21) to connect the lower region of the upper portion of the plurality of hanger parts (600). By doing so, the connecting part (500) can stably reciprocate the plurality of hanger parts (600). Even if the connecting part (500) reciprocates at a high speed, the plurality of hanger parts (600) can reciprocate stably together with the clothing or hanger part (1000) without twisting.

[0121] The entire area of ​​the hanger part (600) may be positioned below the upper surface (22) of the inner case (20).

[0122] The above connecting part (500) may also be positioned lower than the upper surface (22) of the inner case (20) and configured to connect one side of the outer surface or one side of the lower surface of a plurality of the hanger parts (600).

[0123] Thus, the connecting part (500) can be configured to connect a plurality of the hanger parts (600) inside the receiving space (21).

[0124] The connecting part (500) may be positioned in a location that overlaps with the hanger part (600). For example, the connecting part (500) may be positioned between the top and bottom of the hanger part (600).

[0125] The moving hanger (100) of the clothing processing device of the present invention may further include a hanger frame (700) that supports a plurality of the hanger parts (600) inside the receiving space (21).

[0126] The above hanger frame (700) may be provided to support a plurality of hanger parts (600) below the upper surface (22) of the inner case (20).

[0127] For example, the hanger frame (700) may include a support body (712) that extends in the width direction or the front-rear direction within the receiving space (21). A plurality of hanger sections (600) may be spaced apart along the extension direction of the support body (712).

[0128] The above plurality of hanger parts (600) may be rotatably coupled to the support body (712) and may be seated on the support body (712) in any manner.

[0129] For example, a plurality of hanger members (600) may be seated by penetrating the support body (712), and a plurality of hanger members (600) may be seated on the upper part of the support body (712).

[0130] In the following description, the explanation is based on the assumption that a plurality of hanger parts (600) are positioned on the upper part of the support body (712).

[0131] A plurality of hanger members (600) can be rotatably seated on the upper part of the support body (712) while their positions are fixed.

[0132] The above connecting part (500) may be configured to reciprocate on the upper part of the support body (712). Thus, the connecting part (500) and a plurality of the hanger parts (600) may be exposed inside the receiving space (21).

[0133] The above hanger frame (700) may further include a connecting body (711) that fixes the support body (712) inside the receiving space (21). The connecting body (711) may extend upward from both ends of the support body (712) and be fixed to the upper surface (22) of the inner case (20). The connecting body (711) may space the support body (712) downward from the upper surface (22) of the inner case (20) by the length of the connecting body (711). Thus, the hanger part (600) and the connecting part (500) may be positioned between a plurality of the connecting bodies (711) and placed inside the receiving space (21). The connecting part (500) may be positioned to move back and forth between the plurality of connecting bodies (711).

[0134] The moving hanger (100) of the clothing processing device of the present invention may include a driving unit (200) that provides power to reciprocate the connecting unit (500). The driving unit (200) may generate rotational motion that rotates continuously in one direction.

[0135] Meanwhile, if the driving unit (200) is equipped with a motor, the rpm of the motor may be set too high to shake the clothing. If the driving unit (200) is driven at a low rpm suitable for shaking the clothing, the output for shaking the clothing may be insufficient. The moving hanger (100) of the clothing processing device of the present invention may further include a motion conversion unit (300) that lowers the rpm of the driving unit (200) but increases the torque or output.

[0136] The above motion conversion unit (300) may be connected to the above driving unit (200) to transmit the power of the above driving unit as is, while lowering the rpm and increasing the torque. The above motion conversion unit (300) may be positioned on one side of the above driving unit (200) so as to receive the output of the above driving unit (200) with minimal loss, and may be positioned above the above support plate (150).

[0137] The moving hanger (100) of the clothing processing device of the present invention may include a motion conversion unit (300) connected to the driving unit (200) and converting the rotational motion generated by the driving unit (200) into reciprocating rotational motion. Thus, even if the driving unit (200) generates rotational motion that rotates continuously in one direction, the motion conversion unit (300) can convert the rotational motion generated by the driving unit (200) into reciprocating rotational motion and transmit it to the connecting unit (500).

[0138] Accordingly, the drive unit (200) can be continuously maintained without repeating the cycle of driving and stopping during the process of reciprocating the connection unit (500). As a result, the drive unit (200) can be driven at maximum output, and the energy consumption of the drive unit (200) can be reduced.

[0139] The above driving unit (200) may be positioned outside the receiving space (21). For example, the driving unit (200) may be positioned above the upper surface (21) of the inner case (20).

[0140] Thus, the driving unit (200) is prevented from being exposed to hot air and moisture supplied to the receiving space (21), thereby ensuring the durability and stability of the driving unit (200).

[0141] The clothing processing device of the present invention may further include a support frame (150) coupled to the upper surface of the inner case (20) and supporting the driving unit (200).

[0142] The inner case (20) may be provided with a through hole, etc., through which the support frame (150) can be seated by penetrating the upper surface (21). Alternatively, at least a portion of the support frame (150) may be embedded in the inner case (20) by injection molding.

[0143] The support frame (150) may be provided in the shape of a plate that is coupled to and supported by the cabinet (10).

[0144] The support frame (150) may be provided to partition / separate the inside of the receiving space (21) and the outside of the receiving space (21).

[0145] The above-mentioned drive unit (200) may be seated and supported on the upper part of the support frame (150). The support frame (150) may be made of a metal material to support the load and vibration of the drive unit (200).

[0146] The hanger frame (700) may be positioned at the lower part of the support frame (150). The connecting body (712) may be connected to and fixed at the lower part of the support frame (150). Alternatively, the hanger frame (700) may be formed integrally with the support frame (150).

[0147] The support frame (150) may be provided to support the load and vibration of the drive unit (200) and simultaneously support the load of the hanger frame (700), hanger unit (600), connecting unit (500), and clothing mounted on the hanger unit (600).

[0148] Since the motion conversion unit (300) must be connected to the driving unit (200), at least a portion may be provided outside the receiving space (21). The motion conversion unit (300) may be positioned above the upper surface (21) of the inner case (20) and may be supported by the support frame (150).

[0149] Since the above motion conversion unit (300) must be configured to transmit the power of the above driving unit (200) to the above hanger unit (600) or connecting unit (500), at least a portion of it may be placed inside the above receiving space (21). In this case, at least a portion of the above motion conversion unit (300) may extend downward through the support frame (150).

[0150] The moving hanger (100) of the present invention may further include a motion transmission unit (400) that is coupled to or extended from the motion conversion unit (300) and reciprocates the connection unit (500).

[0151] The above motion transmission unit (400) can connect the driving unit (200) and the connecting unit (500) by penetrating the upper surface of the inner case (20) or penetrating the support plate (150).

[0152] The above motion transmission unit (400) may be configured to transmit the power transmitted to the above motion conversion unit (300) to the above connection unit (500).

[0153] The above motion transmission unit (400) may have at least a portion disposed inside the receiving space (21).

[0154] The above motion transmission unit (400) may be coupled to or extended to the motion conversion unit (300) positioned on the upper part of the support plate (150) by penetrating the support plate (150).

[0155] Alternatively, the motion transmission unit (400) may be coupled to or extended to the lower part of the motion conversion unit (300) which extends downward through the support plate (150).

[0156] One end of the motion transmission unit (400) may be connected to or extended to the end of the motion conversion unit (300), and the other end may be extended to the upper part of the support body (712). One side of the motion transmission unit (400) may be connected to the connecting unit (500).

[0157] The above motion transmission unit (400) may be positioned inside the coupling body (711) or at least a portion may be received on the inner surface of the coupling body (711). By doing so, the motion transmission unit (400) may be prevented from being exposed outside the hanger frame (700).

[0158] Consequently, the hanger frame (700) may be positioned within the receiving space (21) with at least a portion located below the upper surface of the inner case (20), and the connecting part (500) and the hanger part (600) supported by the hanger frame (700) may be positioned within the receiving space (21) with the portion located below the upper surface of the inner case (20).

[0159] The above motion conversion unit (300) may be positioned outside the receiving space (21) with at least a portion positioned above the upper surface of the inner case (20), and the above driving unit (200) may be positioned outside the receiving space (21) with the portion positioned above the upper surface of the inner case (20).

[0160] The above motion transmission unit (400) may be positioned within the receiving space (21) such that at least a portion thereof is positioned below the upper surface of the inner case (20).

[0161] The above hanger frame (700) can be connected to the lower part of the support plate (150) and exposed to the receiving space (21).

[0162] The drive unit (200) can be positioned above the support plate (940). By doing so, the drive unit (200) can be positioned outside the receiving space (21) and completely prevented from being exposed to hot air and steam.

[0163] As a result, the safety and performance of the drive unit (200) equipped with electrical components can be ensured, and corrosion of the motion conversion unit (300) that can be made of metal material can be prevented and durability can be ensured.

[0164] Since the above-mentioned hanger part (600) is positioned along the extension direction of the above-mentioned hanger frame (700) at the upper part of the above-mentioned hanger frame (700), it is preferable that the connecting part (500) connected to the above-mentioned hanger part (600) is also positioned on the above-mentioned hanger frame (700). Accordingly, the above-mentioned connecting part (500) can be positioned below the support plate (150). By doing so, the connecting part (500) can effectively transmit power from the above-mentioned driving part (200) to the hanger part (600) which is positioned completely separated from the inside of the receiving space (21), thereby enabling the hanger part (600) to reciprocate.

[0165] The hanger frame (700) can be completely fixed to the upper surface of the inner case (20). For example, the hanger frame (700) is coupled to the lower part of the support plate (150) and formed integrally with the support plate (150), so that the installed position remains fixed and does not change even when the drive unit (200) is driven. As a result, even if the hanger unit (600) moves, the hanger frame (700) can remain fixed in its position without shaking in any direction, such as the width direction or the front-rear direction. Thus, the hanger frame (700) supporting the clothing is fixed, so that vibration or noise is prevented from being transmitted to the outside of the cabinet (10) as much as possible. In addition, even if the hanger unit (600) moves quickly, since the hanger frame (700) is fixed, the drive unit (200), which will be described later, can be configured to operate at maximum output. Therefore, the clothing processing device of the present invention can ensure that noise or vibration does not exceed the permitted range even when shaking clothing at the maximum output of the driving unit, and can operate normally even in environments with strict noise standards, such as at night.

[0166] The above-mentioned hanger unit (600) can support the above-mentioned clothes hanger unit (1000) on its upper side. Thus, when clothing is placed on the above-mentioned clothes hanger unit (1000), the clothing can be placed on the hanger unit (600) together with the above-mentioned clothes hanger unit (1000).

[0167] FIG. 3 illustrates the operation of the moving hanger of the present invention.

[0168] Referring to FIG. 3(a), meanwhile, the hanger part (600) of the present invention may be configured to rotate clockwise or counterclockwise at a position installed on the hanger frame (700). That is, the hanger part (600) may be rotatably seated on the upper part of the hanger frame (700), but the position installed on the hanger frame (700) may be fixed without being variable.

[0169] The above-mentioned hanger part (600) may be configured to reciprocate in a clockwise or counterclockwise direction. Accordingly, the clothes hanger part (1000) mounted on the above-mentioned hanger part (600) can reciprocate left and right from the mounted position.

[0170] For example, the connecting part (500) may be provided to be seated on the upper part of the hanger frame (700) and connected to one side of a plurality of the hanger parts (600).

[0171] The above motion transmission unit (400) may be coupled to the above motion conversion unit (300) and configured to reciprocate in clockwise and counterclockwise directions, and the above connecting unit (500) may be coupled to one side of the above motion transmission unit (400) and configured to reciprocate the upper part of the hanger frame (700).

[0172] The above hanger part (600) can be rotated clockwise by the above connecting part (500) when the above driving part (200) is operated.

[0173] Referring to FIG. 3(b), the hanger part (600) can be rotated counterclockwise by the connecting part (500) if the driving part (200) operates for a longer period.

[0174] As this process is repeated, the hanger unit (600) can reciprocate left and right. The hanger unit (600) may be configured to reciprocate left and right while fixed in a fixed position. The hanger unit (600) may be fixed in position on the hanger frame (700) so that its position does not change in the vertical, horizontal, and width directions.

[0175] The above-mentioned hanger unit (600) may be configured to reciprocate at a certain angle for less than one full rotation while the center of rotation is fixed. As a result, no matter how fast the above-mentioned hanger unit (600) rotates, the above-mentioned hanger unit (1000) remains in a fixed position and rotates or moves to one side and to the other side. Therefore, the vibration energy generated in the above-mentioned hanger unit (1000) can be canceled out. Consequently, vibration and noise transmitted to the above-mentioned moving hanger (100) inside the inner case (20) can be minimized.

[0176] As a result, the garment processing device of the present invention can rotate the drive unit (200) at a higher RPM to reciprocate the hanger unit (600) at a faster frequency or stronger output. By doing so, the garment processing device of the present invention can shake the garment with a stronger output. In addition, the garment processing device of the present invention can more reliably remove foreign substances attached to the garment through the moving hanger (100) and more effectively remove wrinkles from the garment. In addition, the garment processing device of the present invention can excite the garment more quickly and expose it to the supplied steam for a longer period. Furthermore, the garment processing device of the present invention can freely adjust the RPM of the drive unit (200) to adjust the drive frequency or drive cycle of the motion transmission unit (400) to suit the course.

[0177] FIG. 4 illustrates an embodiment of the structure of the moving hanger of the present invention.

[0178] The above hanger frame (700) may include a main support member (710) that can support the connecting member (500) and allow the hanger member (600) to be seated in the receiving space (21).

[0179] The main support member (710) may be fixed to the upper surface of the inner case (20) or the support plate (150) and may be positioned on the upper surface of the inner case (20) or the lower surface of the support plate (150).

[0180] The main support member (710) needs to be spaced a certain distance from the upper surface of the inner case (20) or the support plate (150) in order to secure a space where a clothes hanger member (1000) is mounted on the upper part or where the hanger member (600) and the connecting member (500) are installed.

[0181] To this end, the main support member (710) may include a connecting body (711) that is connected to the upper surface of the inner case (20) or the supporting plate (150), and an extension body (712) that is connected to or extends from the connecting body (711) and extends in the width direction of the inner case (20).

[0182] The extension body (712) may be provided in a bar type or a long plate shape to provide a space for the hanger part (600) and the connecting part (500) to be installed, as well as to support the load of the clothing.

[0183] The above-mentioned connecting body (711) may be provided to fix the above-mentioned extension body (712) inside the receiving space (21) at a certain distance from the upper surface of the inner case (20) or the support plate (150).

[0184] The above-mentioned connecting body (711) may be extended or connected at both ends of the above-mentioned extension body (712) and extended upward. Thus, the connecting part (500) may be arranged lengthwise in the width direction of the above-mentioned extension body (712) inside a plurality of the above-mentioned connecting bodies (711).

[0185] The above-mentioned connecting body (711) may be provided with a thickness equal to or longer than that of the above-mentioned extension body (712), and may be provided with a width in the left-right direction that is narrower than the width in the front-back direction. By doing so, the length of the above-mentioned extension body (712) is secured to be as long as possible, allowing more hanger parts (600) to be installed.

[0186] The upper surface of the extension body (711) can be arranged relatively flat. Thus, a plurality of hanger parts (600) can be installed at the same height, and the connecting part (500) can reciprocate while maintaining its height in the width direction.

[0187] The above hanger portion (600) may include a rotating hanger (610) that is seated on the upper part of the extension body (711) and on which the clothes hanger portion (1000) can be mounted, and a hanger shaft (620) that extends from the lower part of the rotating hanger (610) and forms the rotation center of the rotating hanger (610).

[0188] The above-mentioned rotating hanger (610) may be provided in a cylindrical shape. Thus, even if it rotates at a large angle, the volume or space occupied is fixed, so interference with other hanger parts (600) or clothes hanger parts (1000) mounted on other hanger parts (600) can be prevented in advance.

[0189] The above-mentioned rotating hanger (610) is provided with a larger diameter than the above-mentioned hanger shaft (620) to secure an area on which the above-mentioned clothes hanger part (1000) is mounted.

[0190] The above hanger shaft (620) may be extended or connected at the lower center of the rotating hanger (610). The above hanger shaft (620) may be rotatably connected to the upper part of the extension body (912).

[0191] The above-mentioned hanger portion (600) may further include a link coupling portion (630) that extends from one side of the rotating hanger (610) or the hanger shaft (620) and is coupled to the connecting portion (500). The link coupling portion (630) may be positioned on the outer surface rather than the center of the rotating hanger (610) or the hanger shaft (620), or may be provided by extending further outward from the outer surface. Thus, even if the link coupling portion (630) moves simply back and forth left and right, the rotating hanger (610) or the hanger shaft (620) can easily reciprocate, and a sufficient angle of rotation can be ensured.

[0192] The above connecting portion (500) may be configured to connect all of the link coupling portions (630) provided on the plurality of the above hanger portions (600). The length of the above connecting portion (500) may be formed to be equal to or longer than the length at which the plurality of the above hanger portions (600) are spaced apart, and may be formed to be shorter than the length of the above extension body (712). Thus, all of the above hanger portions (600) can be connected to the above connecting portion (500). In addition, a space may be secured at the upper part of the above extension body (712) in which the above connecting portion (500) can reciprocate left and right along the extension direction of the above extension body (712).

[0193] The width of the above connecting part (500) can be formed to be shorter than the width of the above extension body (712).

[0194] The main support member (710) may include a guide groove (713) that provides a space for the connecting member (500) to reciprocate at least one of the two ends of the extension body (712), and a support projection (714) positioned at the rear or front of the guide groove (713) to support both ends of the connecting member (500). The support projection (714) may be formed in a shape in which an exposed surface that can contact or face the connecting member (500) is extended in the left-right direction and protrudes from the upper part of the extension body (712).

[0195] Thus, the connecting part (500) can be guided to move back and forth in the left and right directions by having both ends supported by at least one of the support protrusions (714) arranged on both sides.

[0196] The above connecting part (500) can be positioned at the front or rear of the hanger shaft (610).

[0197] The above hanger frame (700) may further include an auxiliary support member (720) that is seated on the upper part of the main support member (710) and positioned at the rear or front of the hanger shaft (610) to support the hanger member (600).

[0198] The above auxiliary support member (720) may include an auxiliary body (721) that extends along the extension body (711), and an auxiliary hole (722) that penetrates the auxiliary body (721) or is recessed in the extension surface of the auxiliary body (721) so that at least a part of the hanger shaft (610) can penetrate it.

[0199] The length of the auxiliary body (721) may correspond to the spacing between the support protrusions (714), and the height of the auxiliary body (721) may be formed to be smaller than the length of the hanger shaft (610).

[0200] The above auxiliary body (721) can prevent the bearing (800), which is rotatably provided on the hanger shaft (620) and the extension body (712) and will be described later, from being accidentally dislodged.

[0201] Additionally, the auxiliary body (721) may be positioned at the bottom of the rotating hanger (610) and may be positioned so as to face at least a portion of the bottom of the rotating hanger (610). The auxiliary body (721) may be provided to support the bottom of the rotating hanger (610) when the rotating hanger (610) tilts. By doing so, the rotating hanger (610) and the hanger shaft (620) may be prevented from tilting to one side due to the load applied from the hanger part (900).

[0202] The auxiliary hole (722) may be provided to accommodate at least a portion of the hanger shaft (610) to prevent the hanger shaft (610) from tilting. Additionally, it may guide the position where the bearing and the hanger shaft (610) are installed.

[0203] The length of the extension body (712) may be longer than half the width of the inner case (20). Additionally, the length of the extension body (712) may be extended up to a length corresponding to the maximum width of the receiving space (21). Furthermore, the coupling body (711) may be extended from both ends of the extension body (712) and securely connected to the upper surface of the inner case (20) or the support plate (840) by a plurality of fastening members. Additionally, the main support member (710) is fixed inside the inner case (20) and does not move. As a result, the main support member (710) can stably and sufficiently support the load even when multiple garments are mounted. For example, the main support member (710) can stably and sufficiently support six or more garments regardless of the type of garment. For example, the main support member (710) can support a total of nine or more garments.

[0204] The height of the hanger part (600) is provided to be smaller than its diameter, so that even if the diameter of the hanger part (600) is provided to be relatively small, it can stably support the load of the clothes hanger part (1000). In addition, since the height of the hanger part (600) is provided to be low and the diameter is provided to be large, even if heavy clothing is mounted, the hanger part (600) can stably reciprocate left and right without twisting or tilting.

[0205] Therefore, the hanger portion (600) may be arranged in at least 6 or more places along the longitudinal direction of the extension body (712). For example, the hanger portion (600) may be provided in 9 or more places and arranged along the longitudinal direction of the extension body (712).

[0206] Even if the above-mentioned hanger unit (600) reciprocates, the position installed on the extension body (712) is fixed. Therefore, even if the spacing between the above-mentioned hanger units (600) is narrow, the clothes mounted on the multiple hanger units (600) all reciprocate in the same direction, so the possibility of them colliding or interfering with each other is low.

[0207] Consequently, the moving hanger (100) of the clothing processing device of the present invention may be configured to hold and shake six or more garments. For example, the moving hanger (100) of the clothing processing device of the present invention may be configured to hold and shake nine or more garments simultaneously.

[0208] FIG. 5 illustrates an embodiment in which the above-mentioned hanger part can be installed.

[0209] The auxiliary support member (720) is positioned to face the connecting member (500), so that the hanger shaft (610) can be positioned between the auxiliary support member (720) and the connecting member (500).

[0210] The above auxiliary support member (720) may further include a through hole (723) penetrating the auxiliary body (721). The through hole (723) may provide a space through which a fastening member passes to connect the auxiliary body (721) to the upper part of the extension body (712).

[0211] The above-mentioned through hole (723) may be formed along the extension direction of the auxiliary body (721). For example, the through hole (723) may be formed at both ends of the auxiliary hole (722) to more securely fix a bearing positioned at the bottom of the auxiliary hole (722).

[0212] The above-mentioned rotating hanger (610) may be configured to rotate around a hanger shaft (620) installed on the extension body (712) through the above-mentioned auxiliary hole (722).

[0213] The above auxiliary hole (722) may be provided so that one side facing the connecting part (500) is open. By doing so, the link coupling part (630) extending from one side of the hanger part (600) can be prevented from interfering with the auxiliary support part (720).

[0214] Meanwhile, the above connecting part (500) can be connected to the link connecting part (630) of a plurality of the above hanger part (600) along the extension direction.

[0215] The above connecting part (500) may be connected to the motion transmission part (400) and configured to receive power from the driving part (200) and move back and forth in the direction in which the plurality of hanger parts (600) are arranged.

[0216] The above connecting part (500) can be coupled to the above motion transmission part (400) at one end.

[0217] The above motion transmission unit (400) may include a reciprocating shaft (420) coupled to the above connecting unit (500). The reciprocating shaft (420) may be configured to continuously reciprocate in clockwise and counterclockwise directions when the driving unit (200) is driven. The principle of driving the reciprocating shaft (420) will be described later.

[0218] For example, the reciprocating shaft (420) may include a shaft body (421) that rotates according to the power of the driving unit (200), and a shaft coupling part (42) that extends from the shaft body (421), rotates together with the shaft body (421), and is coupled to the connecting part (500).

[0219] The shaft coupling portion (422) is formed by extending outward from the shaft body (421) and can be positioned on the outside of the shaft body (421). Thus, when the connecting portion (500) is coupled to the shaft coupling portion (422), the connecting portion (500) can be positioned on one side of the shaft body (421) or in a tangential direction. Thus, when the shaft coupling portion (422) reciprocates clockwise and counterclockwise, the connecting portion (500) can reciprocate left and right relative to the shaft body (421).

[0220] The further the shaft coupling part (422) is separated from the diameter of the shaft body (421), the greater the displacement of the outer surface that occurs when the shaft coupling part (422) reciprocates. Accordingly, the displacement that the connecting part (500) can reciprocate also becomes greater, so that the hanger part (600) can be reciprocated up to a set angle.

[0221] The shaft coupling portion (422) may be provided in the shape of a disc with a diameter larger than the diameter of the shaft body (421). The shaft coupling portion (422) may be coupled to the connecting portion (500) while supporting the connecting portion (500).

[0222] The end of the above connecting part (500) may be coupled to the shaft coupling part (422). The reciprocating shaft (420) may include a shaft support part (423) extending from the shaft coupling part (422) to be coupled to the above connecting part (500).

[0223] The shaft coupling part (422) or the shaft support part (423) may be positioned at the same height as the link coupling part (630). Thus, even if the connecting part (500) is provided in the shape of a straight plate, it can be simultaneously connected to the reciprocating shaft (420) and the link coupling part (630).

[0224] FIG. 6 illustrates an embodiment in which the above-mentioned hanger part can be rotated.

[0225] The above motion transmission unit (400) may further include a transmission shaft (410) that receives power from a motion conversion unit (300) or a driving unit (200) that is extended in the vertical direction and positioned above the support plate (150).

[0226] The above transmission shaft (410) may be configured such that its end is connected to or extended by the reciprocating shaft (420) so that the connecting body (711) extends upward along the extension direction.

[0227] The above transmission shaft (410) may be provided in the shape of a pipe or cylinder, with one end connected to the motion conversion unit (300) and the other end connected to the reciprocating shaft (420).

[0228] The above transmission shaft (410) may have a coupling member (412) formed at the top that is coupled to the motion conversion unit (300), and may further include a protruding ring (411) that can be seated on the support plate (150) or a support bearing (820) in an area penetrating the support plate (150).

[0229] The protruding ring (411) may be provided in the form of a ring that is coupled to the outer surface of the transmission shaft (410), or may be provided in a shape in which the diameter of the transmission shaft (410) is thicker than the diameter of another region.

[0230] The above protruding ring (411) can be supported by being seated on either the upper or lower surface of the support plate (150).

[0231] The upper part of the shaft body (421) may be provided with a chamfered portion (4211) that can be coupled to the lower part of the transmission shaft (410). The chamfered portion (4211) may be formed in a shape that is recessed or protrudes from the upper part of the shaft body (421) to accommodate a part of the lower part of the transmission shaft (410) or to be accommodated at the lower part of the transmission shaft (410).

[0232] The chamfered portion (4211) may be provided in a polygonal shape to more effectively receive the rotational force of the transmission shaft (410).

[0233] The shaft body (421) may be provided to be coupled to or extended at the end of the transmission shaft (410) so as to rotate together with the transmission shaft (420). The shaft support portion (423) may be provided in the form of a rib extending from the upper part of the shaft coupling portion (422) or the outer surface of the shaft body (421) while being supported by the shaft coupling portion (422).

[0234] The above reciprocating shaft (420) may include a connecting member (424) that is provided on the upper part of the shaft support member (423) and coupled to the connecting member (500).

[0235] For example, the connecting part (424) may be provided in the form of a projection that protrudes from the shaft support part (423) and is coupled to the connecting part (500).

[0236] The above connecting part (500) may include a link body (510) that extends in the width direction of the inner case (20) or in the extension direction of the extension body (712) to connect the reciprocating shaft (420) and a plurality of the hanger parts (600), and a link fastening part (520) that is detachably coupled to the link body (510) and the connection coupling part (434) and the link coupling part (630).

[0237] For example, the link connecting part (520) may be provided as a hole or groove formed by penetrating the link body (510) or by being recessed into the lower part of the link body (510).

[0238] The above shaft support (423) can be positioned at the same height as the above link coupling (630).

[0239] The above-mentioned rotating hanger (610) may be detachably provided with the above-mentioned hanger shaft (620).

[0240] The above hanger shaft (620) and the above link coupling part (630) can be formed integrally.

[0241] The link coupling portion (630) may be provided in the form of a rib extending parallel to the shaft support portion (423) on the hanger shaft (620). The link coupling portion (630) may be detachably coupled to the link fastening portion (520).

[0242] For example, the link coupling part (630) may have a link projection formed on its upper surface that is detachably coupled to the link fastening part (520).

[0243] When the above reciprocating shaft (420) reciprocates in clockwise and counterclockwise directions, the link body (510) reciprocates along the direction in which the hanger part (600) is arranged or in the width direction, and the hanger part (600) is coupled to the link connecting part (520) and can reciprocate in clockwise and counterclockwise directions.

[0244] FIG. 7 illustrates an example of the structure of the above-mentioned hanger part.

[0245] FIG. 7(a) is a view of the hanger unit (600) from above, and FIG. 7(b) is a view of the hanger unit (600) from below.

[0246] The above-described rotating hanger (610) may include a cylindrical hanger body (611), a seating groove (612) recessed in the upper part of the hanger body (611) into which the clothes hanger part (1000) is inserted, and a coupling groove (613) provided in the lower part of the seating groove (612) to support the clothes hanger part (1000).

[0247] The above hanger body (611) may be provided with a diameter larger than its height. This allows the maximum possible surface area to be supported on the hook formed in the clothes hanger part (1000).

[0248] The above-mentioned seating groove (612) may be formed such that its width corresponds to the thickness of the loop of the hanger part (1000), and may be formed by being recessed in the diameter direction of the hanger body (611). The length of the above-mentioned seating groove (612) may correspond to the diameter of the hanger body (611). That is, the above-mentioned seating groove (612) may be formed by being recessed downward from the upper part of the hanger body (611) in an area corresponding to the diameter of the hanger body (611). Thus, the above-mentioned seating groove (612) may be formed to be the longest in the hanger body (611). In addition, even if the diameter of the hanger body (611) is formed to be smaller than the width of the loop formed at the top of the hanger part (1000), the loop of the hanger part (1000) can be stably seated on the hanger body (611).

[0249] The coupling groove (613) may be formed with the shape of the upper lower part of the hook of the hanger part (1000) or a curvature corresponding to the hook. For example, the coupling groove (613) may be formed convex upward. By doing so, the surface area of ​​the hanger part (600) that can make surface contact with the hook of the hanger part (1000) can be increased.

[0250] The above-mentioned rotating hanger (611) may have a coupling hole (614) formed at the bottom to which the hanger shaft (620) is coupled.

[0251] The coupling hole (614) may have a groove on its inner surface into which the upper end of the hanger shaft (620) can be inserted, or it may have a shape that engages with a fastening projection (622) formed on the upper end of the hanger shaft (620).

[0252] The coupling hole (613) may be provided in a circular shape, and the shape that engages with the outer surface of the fastening projection (622) inside may be provided in a polygonal shape. The coupling hole (613) may be formed in the lower center of the rotating hanger (611).

[0253] The above hanger shaft (620) may include a rotating body (621) formed such that its height is greater than its diameter. The rotating body (621) may be provided in a cylindrical shape and may form the center of rotation of the hanger part (600). The diameter of the rotating body (621) may be formed to be smaller than the diameter of the hanger body (611).

[0254] The upper part of the rotating body (621) may be provided with a fastening projection (622) that protrudes to engage with the inner surface of the coupling hole (613). The fastening projection (622) may be formed smaller than the area of ​​the hanger body (611) and may be formed in a polygonal shape.

[0255] Thus, when the hanger shaft (620) is coupled to the rotating hanger (610), it can be fixed so that it does not rotate arbitrarily on the rotating hanger (610). Therefore, the hanger shaft (620) can rotate integrally with the rotating hanger (610).

[0256] The above link coupling part (630) may include a link rib (631) extending from the rotating body (621) and a protruding projection (632) protruding from the link rib (631).

[0257] The link rib (631) may be provided in a rib shape that extends longer than the diameter of the rotating body (621) and may be provided to support the link body (510).

[0258] The above protruding projection (632) is detachably inserted into the link fastening part (520) and can transmit power from the link body (510) to the hanger body (611).

[0259] FIG. 8 illustrates an embodiment in which the above-mentioned hanger unit reciprocates.

[0260] Referring to FIG. 8(a), when the reciprocating shaft (430) rotates and the link body (510) moves to the left, the link coupling part (630) coupled to the link body (510) can rotate clockwise.

[0261] When the link coupling part (630) rotates clockwise, the hanger shaft (620) and the rotating hanger (610) can also rotate clockwise. In a plurality of hanger parts (600), the link coupling shaft (630) extending from the rotating hanger (610) is coupled to the link body (510) at the same angle. Therefore, the plurality of hanger parts (600) can all rotate clockwise simultaneously and temporarily.

[0262] Thus, the clothes hanger part (1000) mounted on the rotating hanger (610) can also rotate clockwise.

[0263] Referring to FIG. 8(b), when the reciprocating shaft (430) rotates in the opposite direction and the link body (510) moves to the right, the link coupling part (630) coupled to the link body (510) can rotate counterclockwise.

[0264] The link coupling part (630) coupled to the link body (510) can rotate counterclockwise.

[0265] When the link coupling part (630) rotates counterclockwise, the hanger shaft (620) and the rotating hanger (610) can also rotate counterclockwise. In a plurality of hanger parts (600), the link coupling shaft (630) extending from the rotating hanger (610) is coupled to the link body (510) at the same angle. Therefore, the plurality of hanger parts (600) can all rotate counterclockwise simultaneously and temporarily. As a result, the clothes hanger part (1000) mounted on the rotating hanger (610) can also rotate counterclockwise.

[0266] When the above motion transmission unit (400) reciprocates, the corresponding process can be repeated.

[0267] The link body (510) can move back and forth left and right, and a plurality of hanger parts (600) can also rotate back and forth left and right. The clothes hanger part (1000) and the clothes mounted on the clothes hanger part (1000) can also rotate back and forth.

[0268] FIG. 9 illustrates a configuration for shielding the above-mentioned hanger frame.

[0269] The above hanger frame (700) extends in the width direction within the receiving space (21) so as to hold six or more garments at once, and the above hanger part (600) is provided in multiple numbers so as to hold six or more garments and is seated on the upper part of the above hanger frame (700) exposed within the receiving space (21).

[0270] As a result, the hanger frame (700) is exposed to the receiving space (21), and the hanger part (600) is also exposed to the receiving space, so the connecting part (500) can also be exposed to the receiving space.

[0271] However, when a drying course or refresh course for processing clothing is performed in the above-mentioned receiving space (21), one or more of steam and hot air may be supplied. If the hanger part (600) and the connecting part (500) are exposed to the hot air and steam, the hanger part (600) and the connecting part (500) may be heated or corroded, and there is a concern that the durability of the hanger part (600) and the connecting part (500) may not be guaranteed.

[0272] In addition, since the hanger part (600) and the connecting part (500) are movable components, there is a risk that the fabric mounted on the hanger part (600) may come into contact with the connecting part (500), etc. and be damaged.

[0273] Furthermore, foreign substances discharged from the clothing, etc. may adhere to and contaminate the hanger part (600) and the connecting part (500), and the foreign substances may be introduced into the fastening part of the hanger part (600) and the connecting part (500), causing the fastening state to become poor.

[0274] Since the above motion transmission unit (400) is configured to transmit power from the driving unit (200), it may be provided with a sturdy metal material. The motion transmission unit (400) may be heated or corroded if exposed to hot air and steam.

[0275] The connection state between the motion transmission unit (400) and the connection unit (500) may be poor due to reasons such as foreign substances being introduced into the part where the motion transmission unit (400) and the connection unit (500) are joined.

[0276] Meanwhile, the above hanger frame (700) may also be permanently deformed if continuously exposed to heat or steam, and the bearing (800) seated on the upper surface of the above hanger frame (700) may also be deformed or corroded.

[0277] Consequently, if the above-mentioned hanger part (600), the above-mentioned connecting part (500), and the above-mentioned motion transmission part (400) are exposed as they are in the above-mentioned receiving space (21), the above-mentioned moving hanger (100) may not operate, the above-mentioned moving hanger (100) may not operate normally, and the state of the above-mentioned moving hanger (100) may not be maintained.

[0278] To prevent this, the garment processing device of the present invention may further include a shielding part (900) provided to surround the hanger frame (700) to prevent at least one of the connecting part (500), the hanger frame (700), the hanger part (600), and the motion transmission part (400) from being exposed to the hot air or steam.

[0279] The shielding part (900) may be provided to accommodate at least one of the hanger frame (700), the connecting part (500), and the motion transmission part (400).

[0280] For example, the shielding part (900) may be provided to completely accommodate the hanger frame (700) and the connecting part (500). Accordingly, the direct exposure of the hanger frame (700) and the connecting part (500) to hot air or steam can be completely blocked, and exposure to foreign substances can also be blocked.

[0281] The shielding portion (900) may be provided to surround the upper, lower, and side of the hanger frame (700). For example, the shielding portion (900) may be provided to block the entire area of ​​the hanger frame (700) from being exposed to the receiving space (21). Thus, the motion transmission portion (400), which can be accommodated in at least a portion of the hanger frame (700), may also be covered by the shielding portion (900). The motion transmission portion (400) may be placed inside the shielding portion (900) to block at least a portion from being exposed to the receiving space (21). The motion transmission portion (400) may also be blocked from being exposed to steam, hot air, or foreign substances.

[0282] The shielding portion (900) may be provided to accommodate at least a portion of the hanger portion (600). However, even if the shielding portion (900) accommodates or encloses the hanger frame (700), the upper surface of the hanger portion (600) may be exposed to the outside. Thus, the hanger portion (600) is exposed to the outside, allowing the clothes hanger portion (1000) to be mounted without being obstructed by the shielding portion (900).

[0283] Meanwhile, in addition to the upper surface of the hanger part (600), at least a portion of the side or outer surface may be wrapped or received by the shielding part (900). By doing so, the exposure of the hanger part (600) to the receiving space (21) is minimized, thereby ensuring the performance of the hanger part (600).

[0284] The shielding part (900) may be provided with a material that is resistant to heat and moisture. For example, it may be provided with a reinforced resin series.

[0285] The shielding portion (900) may include a receiving cover (910) positioned at the lower part of the hanger frame (700) to shield the hanger frame (700) and the connecting portion (500).

[0286] The receiving cover (910) can accommodate at least a portion of the hanger frame (700) and the connecting part (500). The receiving cover (910) may be provided to cover the lower surface and the front and rear surfaces of the hanger frame (700). The lower surface and the front and rear surfaces of the hanger frame (700) may be blocked from being exposed to the receiving space (21).

[0287] The shielding portion (900) may further include a shielding cover (920) positioned on the upper part of the hanger frame (700) to shield the hanger frame (700) and the connecting portion (500).

[0288] The shielding cover (920) is provided to shield the upper and inner sides of the main support member (710), and the receiving cover (910) may be provided to shield the lower and outer sides of the main support member (710).

[0289] The shielding cover (920) and the receiving cover (910) can be detachably coupled.

[0290] The length of the shielding cover (920) may be provided to be equal to the length of the upper surface of the extension body (712), and the front-rear width of the shielding cover (920) may be provided to be longer than the width of the extension body (712). Accordingly, the lower surface of the front-rear side of the shielding cover (920) may be exposed to the outside of the extension body (712).

[0291] The length of the receiving cover (910) may be provided with a length corresponding to the distance to both ends of the connecting body (711). That is, the length of the receiving cover (910) may be provided to be equal to or longer than the length of the extension body (712).

[0292] The width of the receiving cover (910) may be longer than the width of the extension body (712), and the height of the receiving cover (910) may be longer than the height of the extension body (712). Thus, the upper surface of the front and rear sides of the receiving cover (910) may be exposed to the outside of the extension body (712).

[0293] The lower surface of the shielding cover (920) can be joined to the upper surface of the receiving cover (910) and fixed together. Thus, the receiving cover (910) and the shielding cover (920) can be supported on the hanger frame (700) while wrapping around the hanger frame (700).

[0294] Meanwhile, the shielding portion (900) may further include side covers (930) that shield both sides of the main support portion (710). The side covers (930) may be provided as plates having a shape corresponding to the shape of the coupling body (711). The side covers (930) may be received or coupled and fixed at both ends of the receiving cover (910).

[0295] FIG. 10 illustrates a detailed structural embodiment of the shielding part.

[0296] The shielding cover (920) may include an inner cover (921) that shields the inner surface of the plurality of coupling bodies (711), and a cover body (712) that extends from the lower part of the inner cover (921) and shields the extension body (712) and the connecting part (500).

[0297] The above cover body (712) can be placed on the upper part of the extension body (712) and the connecting part (500).

[0298] The above motion transmission unit (400) may be completely accommodated inside the coupling body (711).

[0299] Alternatively, if at least a portion of the coupling body (711) is accommodated, the motion transmission unit (400) may be positioned between the hanger frame (700) and the shielding cover (712). The motion transmission unit (400) may be accommodated and positioned between the coupling body (711) and the inner cover (921).

[0300] The shielding cover (920) may further include an exposure hole (923) that exposes the upper surface of the hanger part (600).

[0301] The above hanger portion (600) may be rotatably positioned inside the exposure hole (923). The diameter of the exposure hole (932) may be provided to correspond to the diameter of the rotating hanger (610).

[0302] Meanwhile, the shielding cover (920) may further include an exposure groove (924) that exposes the outer surface of the rotating hanger (610) by opening both sides of the exposure hole (923) or the front and rear inner surfaces of the exposure hole (9320).

[0303] The above-mentioned exposed groove (924) can be extended from the upper surface of the cover body (922) to open the front and rear sides of the exposed hole (923).

[0304] At least a portion of the above-mentioned rotating hanger (610) may be positioned outside the above-mentioned exposed groove (924).

[0305] Accordingly, the diameter of the above-mentioned rotating hanger (610) can be provided to be slightly larger than the width of the above-mentioned cover body (922).

[0306] Additionally, both ends of the seating groove (612) may be exposed to the outside through the exposure groove (924). Accordingly, the hook of the hanger part (1000) may be positioned between the exposure grooves (924), thereby preventing the hanger part (1000) from interfering with the receiving cover (910).

[0307] Consequently, even if the shielding cover (920) shields the upper portion of the hanger frame (700) and the connecting portion (500) and shields the outer surface of the hanger portion (600), the upper surface of the rotating hanger (610) is exposed through the exposure hole (923), and at least a portion of the side of the hanger portion (600) is exposed minimally through the exposure groove (924), so that the hanger portion (1000) can be mounted on the hanger portion (600) without hindrance.

[0308] The width of the above-mentioned exposed groove (924) may be formed to be equal to or longer than the maximum rotational length of both ends of the above-mentioned mounting groove (612). Thus, even if the above-mentioned hanger part (1000) is inserted into or mounted in the above-mentioned mounting groove (612), the hook part, etc. of the hanger part (1000) exposed outside the above-mentioned mounting groove (612) may be prevented from interfering with the above-mentioned shielding cover (920).

[0309] Meanwhile, the shielding cover (920) may include a pressure projection (926) that protrudes from the lower surface to press the auxiliary support member (720). The pressure projection (926) presses the upper surface of the auxiliary support member (720) toward the main support member (710), thereby preventing the auxiliary support member (720) and the bearing (800) from coming apart.

[0310] The width of the above pressure projection (926) may correspond to the width of the above auxiliary support part (720), and the total length of the above pressure projection (926) may correspond to the total length of the above auxiliary support part (720).

[0311] The shielding cover (920) may include a hanger portion (600) (925) positioned in front of or behind the pressure projection (926) and formed to have a length protruding smaller than that of the pressure projection (926). The hanger portion (600) (925) may be formed protruding from the lower surface of the shielding cover (920). The hanger portion (600) (925) may be positioned spaced apart from the connecting portion (500) to secure a space for the connecting portion (500) to be spaced apart. Additionally, the hanger portion (600) (925) may be coupled to the inner surface of the support projection (714) in the main support portion (710) to completely block air from entering the interior of the connecting portion (500).

[0312] Meanwhile, the shielding cover (920) may include a support groove (927) that is disposed on the outer surface of the inner cover (921) to form a receiving space. The support groove (927) may be provided in a shape corresponding to the inner surface of the coupling body (711). The support groove (927) may be coupled to and fixed to the inner surface of the coupling body (711).

[0313] The above motion transmission unit (400) may be positioned at least partially between the support groove (872) and the coupling body (711) to prevent exposure to the receiving space (21).

[0314] The above receiving cover (910) may be provided such that its upper surface contacts or is coupled with the lower surface of the shielding cover (920).

[0315] The above hanger frame (700) and the above connecting part (500) can be placed inside the shielding cover (920) and the above receiving cover (910) so that they are not exposed to the receiving space (21).

[0316] The above receiving cover (910) may include a receiving body (912) that receives the lower part of the hanger frame (920), and connecting ribs (911) that extend toward the support plate (150) from both ends of the extension body (912).

[0317] The receiving body (910) may be provided to shield the lower and upper surfaces from the rear surface of the main support member (710). The internal shape of the receiving body (910) may be provided to correspond to the external shape of the main support member (710).

[0318] The receiving body (910) may be provided to be in surface contact with the main support part (710).

[0319] The above connecting rib (911) may be extended to shield the exposed surface of the connecting body (711) at the upper ends of the receiving cover (910).

[0320] The above connecting ribs (911) may be provided in multiple numbers to shield the front and rear of the connecting body (711).

[0321] The above receiving body (910) may also be made of a metal material with strong durability and water resistance to enhance aesthetic appeal.

[0322] The above side cover (930) can be inserted into and fixed to the connecting rib (911) and the receiving body (910).

[0323] The above side cover (930) may be connected to the outside of the above connecting body (711) through a fastening member, etc.

[0324] FIG. 11 illustrates the operation process of the hanger unit with the shielding unit installed.

[0325] Referring to FIG. 11(a), when the driving unit (200) is driven and the motion transmission unit (400) is fully rotated to either the left or the right, the connecting unit (500) moves completely to either the left or the right, and the seating groove (612) can be rotated until it is adjacent to either the front or the rear of the exposed hole (924).

[0326] The internal configuration of the above motion transmission unit (400) and the above connection unit (500) is not exposed due to the shielding unit (900), and the combined area of ​​the above connection unit (500) and the above hanger unit (600), or the combined area of ​​the above connection unit (500) and the above motion transmission unit (400), may not be exposed to the outside.

[0327] Referring to FIG. 11(b), when the driving unit (200) is continuously driven, the motion transmission unit (400) rotates to the center area of ​​the left and right sides, the connecting unit (500) moves to the center area of ​​the left or right side, and one end of the seating groove (612) can rotate to the center area of ​​the two sides of the exposure hole (924).

[0328] Referring to FIG. 11(c), when the driving unit (200) is continuously driven further, and the motion transmission unit (400) is in a state where it is fully rotated in either the left or right direction, the connecting unit (500) moves completely in either the left or right direction, and the seating groove (612) can be rotated until it is adjacent to the other side of the exposure hole (924) provided in either the front or the rear.

[0329] Consequently, throughout the entire process, the upper surface of the hanger body (611) is exposed to the outside, and only the area of ​​the side or outer surface of the hanger body (611) exposed to the exposed groove (942) may be exposed to the outside. That is, most of the area of ​​the side of the outer surface of the hanger body (611), as well as the hanger shaft (620), the link coupling part (630), etc., can be completely blocked from being exposed to the receiving space (21).

[0330] The upper surface of the hanger body (611) can be positioned lower than the cover body (922). By doing so, the exposure of the hanger part (600) to the receiving space (21) can be minimized.

[0331] Of course, the upper surface of the hanger body (611) may be positioned above the cover body (922). In this case, the clothes hanger part (1000) can be more easily seated and supported on the hanger part (600).

[0332] FIG. 12 illustrates the internal state of the shielding part.

[0333] The main support member (710) and the connecting member (500) can be accommodated in the shielding member (900) so that they are completely blocked from being exposed to the accommodation space (21). At least one of the main support member (710) and the connecting member (500) can be completely placed inside the shielding member (900).

[0334] The main support member (710) may be provided with a hanger member (600) (716) in which the hanger shaft (620) is rotatably received in the extension body (712). The hanger member (600) (716) may be provided in multiple numbers and arranged along the longitudinal direction of the extension body (712). The hanger member (600) (716) may be provided in a number corresponding to the hanger member (600) and may be formed at the location where the hanger member (600) is installed.

[0335] The above hanger part (600) (716) may be provided by having the upper surface of the extension body (712) recessed.

[0336] The bearing (800) may be coupled inside the mounting groove (716) to rotatably support the hanger shaft (620). The diameter of the mounting groove (716) may be provided to be much larger than the diameter of the hanger shaft (620). The inner circumferential diameter of the mounting groove (716) may be provided to correspond to the outer circumferential diameter of the bearing (800). The depth of the mounting groove (716) may be provided to be equal to or deeper than the thickness or height of the bearing (800).

[0337] The plurality of bearings (800) can be placed inside the shielding part (900) so as not to be exposed inside the receiving space (21).

[0338] Additionally, the auxiliary support member (720) may be positioned on the upper part of the bearing (800) to prevent the bearing (800) from coming out of the installation groove (716). The auxiliary support member (720) may be positioned inside the shielding member (900) to prevent exposure inside the receiving space (21).

[0339] Additionally, the main support member (710) may further include a support groove (715) in which the reciprocating shaft (430) can be seated and accommodated at either end of the extension body (712). A bearing (800) that rotatably supports the lower end of the reciprocating shaft (430) may additionally be seated in the support groove (715). The inner circumferential diameter of the support groove (715) may be provided to correspond to the outer circumferential diameter of the bearing (800). The depth of the support groove (715) may be provided to be equal to or deeper than the thickness or height of the bearing (800).

[0340] Consequently, the hanger frame (700) is positioned below the upper surface of the inner case (20) or the support plate (150), and the hanger part (600) is positioned below the upper surface of the inner case (20) or the support plate (150), but can be positioned above the hanger frame (700).

[0341] Additionally, the connecting part (500) may also be positioned below the upper surface of the inner case (20) or the support plate (150) so as to be positioned as close as possible to the hanger part (600). As a result, the connecting part (500) that moves back and forth and the reciprocating hanger part (600) that rotates back and forth can be positioned at a height that is as similar as possible. In other words, the area where the clothes hanger part (1000) is seated on the hanger part (600) and the area where the hanger part (600) is coupled to the connecting part (500) can be positioned as close as possible.

[0342] Additionally, the connecting part (500) can maintain a state in which its upper and lower parts are pressed against the receiving cover (910) and the main support part (710). Therefore, even if a strong external force is transmitted from the driving part (200) and the motion transmission part (400) or the direction of movement is changed at a rapid speed, the connecting part (500) can stably reciprocate in the extension direction or left and right direction of the main support part (710) without detaching from the main support part (710) in the upper or lower direction or forward and backward direction.

[0343] Thus, even if a large amount of clothing load is applied to multiple hanger sections (600), the connecting section (500) can stably reciprocate the hanger sections (600). Therefore, the moving hanger (100) of the present invention is equipped with nine or more hanger sections (600), and even if nine pieces of clothing are mounted on all hanger sections (600), the connecting section (500) can stably reciprocate all hanger sections (600) simultaneously.

[0344] FIG. 13 illustrates an embodiment of the driving unit of the moving hanger of the present invention.

[0345] The above driving unit (200) may be positioned on the upper part of the support plate (150) and configured to directly rotate the motion transmission unit (400).

[0346] The above driving unit (200) may be equipped with a simple motor.

[0347] The drive unit (200) is mounted on the upper part of the support plate (150), and the power transmission unit can pass through the support plate (150) to connect the drive unit (200) and the connecting unit (500) mounted on the hanger frame (700).

[0348] The above driving unit (200) is positioned above the support plate (150) so that it can be blocked from exposure to hot air and steam supplied to the inner case (20).

[0349] The motion conversion unit (300) may be configured such that one end is connected to the driving unit (200) and extends toward the receiving space (21) or the support plate (150). The motion conversion unit (300) may be configured to convert the rotational power of the driving unit (200) into reciprocating power.

[0350] The above driving unit (200) and the above motion conversion unit (300) can both be seated on a support plate (150) and positioned outside the receiving space (21).

[0351] FIG. 14 illustrates the structure of the drive unit shown in FIG. 13.

[0352] The above driving unit (200) may include a motor unit (210) that generates power by receiving electricity, and a rotating unit (220) that can rotate continuously in one direction by the motor unit (210).

[0353] The above driving unit (200) may be configured to repeatedly rotate the above rotating unit (220) clockwise and stop, and rotate counterclockwise and stop, rather than continuously rotating the above rotating unit (220) in one direction. In this case, the volume of the above driving unit (200) is reduced, which has the effect of reducing the weight of the above moving hanger (100).

[0354] The above-mentioned rotating part (220) may be configured to rotate continuously by the above-mentioned motor part (210) to generate a rotational motion that rotates in one direction.

[0355] For example, the rotating part (220) may include a drive shaft (221) that rotates by being directly connected to the motor (210), and an eccentric shaft (222) that rotates by power transmitted from the drive shaft (211) and rotates along a certain radius.

[0356] The above driving unit (200) may further include a transmission unit (230) configured to transmit power of the rotation shaft (221) to the eccentric shaft (222).

[0357] The above transmission unit (230) may include a power pulley (231) coupled to the vertical rotation shaft (220) and rotating together with the vertical rotation shaft (220), a transmission pulley (232) on which the displacement generating unit (300) is seated, and a belt (233) connecting a portion of the outer surface of the power pulley (231) and the transmission pulley (232).

[0358] The above transmission unit (230) may further include a pulley support unit (234) that rotatably supports the transmission pulley (232). The pulley support unit (234) may be provided so that the transmission pulley (232) and the power pulley (231) are positioned at the same height. The pulley support unit (234) may be seated on the support plate (940) to support the transmission pulley (232).

[0359] The diameter of the transmission pulley (232) may be provided to be much larger than the diameter of the power pulley (231). Accordingly, the rpm of the transmission pulley (232) may rotate less than the rpm of the power pulley (231).

[0360] The above-mentioned rotating part (220) may further include a shaft fixing part (223) that firmly fixes the eccentric shaft (222) to the transmission pulley (232).

[0361] The drive shaft (221) may be configured to rotate continuously in one direction by the motor unit (210) while the center of rotation is fixed. That is, the drive shaft (221) may be configured to rotate.

[0362] The above eccentric shaft (222) may be configured to rotate continuously in one direction along a rotational radius spaced apart from the center of rotation. The entire eccentric shaft (222) may rotate in a circular motion and may generate a displacement for the motion conversion unit (300) to reciprocate the connecting unit (500).

[0363] The hanger frame (700) and the shielding part (900) are coupled to the lower part of the support plate (150) so that they can be completely separated from the driving part (200).

[0364] The moving hanger (100) of the present invention may be configured to transmit power from the driving unit (200) to the motion transmission unit (400) to transmit power to all hanger units (600).

[0365] The moving hanger (100) of the present invention may include a motion conversion unit (300) capable of lowering the rpm and increasing the torque from the power generated by the driving unit (200).

[0366] The above motion conversion unit (300) can be seated on the upper surface of the support plate (150) together with the above driving unit (200).

[0367] One end of the motion transmission unit (400) is coupled to the motion conversion unit (300) and can be extended downward by penetrating the upper surface of the support plate (150) or the inner case (20).

[0368] The above motion transmission unit (400) may be provided so as to be connected to the motion conversion unit (300) by being bent at an axis that extends downward at one end.

[0369] The motor (210) can be seated on the upper surface of the support plate (150).

[0370] The above motor (210) may be provided as a vertical motor (211) in which the rotation axis (220) is arranged in a vertical direction. In this case, the rotation axis (220) can be considered to be provided as a vertical rotation axis.

[0371] The above eccentric shaft (222) rotates more slowly than the drive shaft (221) but can rotate with a stronger torque than the rotation shaft (210).

[0372] The above motion conversion unit (300) may include a rotary connector (310) connected to the eccentric shaft (222) and an extension shaft (320) extending from one end of the rotary connector (310) toward the support plate (150).

[0373] The above-mentioned rotary cannulator (310) may be connected to the above-mentioned eccentric shaft (222) and configured to move back and forth as it rotates continuously in one direction of the above-mentioned eccentric shaft (222).

[0374] The rotary connector (310) may be provided in a plate shape that faces at least a portion of the transmission pulley (232), and the extension shaft (320) may be provided in a pipe shape and extend downward from the end of the rotary connector (310).

[0375] The moving hanger (100) of the present invention may further include a support bearing (820) that rotatably fixes the extension shaft (320) to the support plate (150).

[0376] The extension shaft (320) may be provided to penetrate the support plate (150) and may be rotatably supported on a support bearing (820) that is seated in a through hole (151) formed in the support plate (150).

[0377] The inner case (20) may be provided with a through hole (23) by having a portion of the support plate (150) seated on the upper surface (22). The through hole (23) may be arranged along the width direction of the inner case.

[0378] The clothing processing device (1) of the present invention may further include a support frame (11) that is positioned outside the inner case and supports the cabinet (10).

[0379] The support frame (11) may be provided with a metal material that maintains the appearance of the clothing processing device by being positioned at each location corresponding to the corners of the cabinet (10) or the corners of the inner case (20). The support plate (150) may be supported by having both ends seated on the support frame (12). Accordingly, the load or impact of the moving hanger (100), such as the driving unit (200) and the motion conversion unit (300), can be prevented from being transmitted to the upper surface (22) of the inner case.

[0380] FIG. 15 illustrates the internal configuration of the driving unit and the displacement generating unit.

[0381] The above motor (210) may be coupled to a magnet (212) corresponding to a rotor on the outer surface of the drive shaft (221), and may be equipped with a stator (211) that rotates the magnet of the drive shaft (221) by receiving power to form a rotating magnetic field.

[0382] The pulley support member (234) may include a support member body (241) seated on the support plate (150), a support rotation shaft (242) provided inside the support member body (241) to form the rotation axis of the transmission pulley (232), and a support bearing (243) seated at the center of the support member body (241) to rotatably support the support rotation shaft (242).

[0383] The shaft fixing part (223) is coupled and fixed to the rotation center of the above transmission pulley (232), and an eccentric shaft (222) can be disposed on the upper part of the shaft fixing part (223) so as to be eccentric with respect to the support rotation shaft (242) to reciprocate the motion conversion part (300).

[0384] FIG. 16 illustrates the operating principle of the moving hanger shown in FIG. 14.

[0385] When the drive shaft (221) is rotated by the motor (210), the drive shaft (221) can rotate the transmission part (230).

[0386] When the above moving hanger (100) is driven, the motor (210) can continuously rotate the drive shaft (221) in one direction. The motor (210) can continuously rotate the drive shaft (221) without repeating the rotation and stopping of the drive shaft (221) to reciprocate the hanger unit (600). By doing so, the hanger unit (600) can be reciprocated at the maximum output of the motor (210), and the amount of electrical energy consumed by the motor (210) can also be reduced.

[0387] The power pulley (231) is coupled to the outer surface of the drive shaft (221) and can rotate in the same direction as the rotation shaft (220), and can rotate the belt (233) wound around the outer surface in the same direction. The transmission pulley (232) can rotate in the same direction as the power pulley (231) as the belt (233) wound around the outer surface rotates.

[0388] The above-mentioned transmission pulley (232) can be rotatably coupled to the upper part of the pulley support (234). When the transmission pulley (232) rotates, the eccentric shaft (222) can rotate together with the transmission pulley (232) in the direction in which the transmission pulley (232) rotates.

[0389] If a shaft fixing part (223) for fixing the eccentric shaft (222) is additionally provided on the upper surface of the transmission pulley (232), the eccentric connector (223) and the eccentric shaft (222) can rotate in the same direction simultaneously.

[0390] The above transmission pulley (232) is provided with a resin material, which can reduce the load on the motor (210). However, the above eccentric connector (222) and the above eccentric shaft (223) are provided with a metal material, which can ensure sufficient durability to reciprocate the motion transmission part (400), the connecting part (500), and the hanger part (600).

[0391] When the drive shaft (221) rotates clockwise, the eccentric shaft (223) can also revolve clockwise around the center of the transmission pulley (232).

[0392] That is, when a quadrant is drawn based on the center of the transmission pulley (232), the above transmission pulley (232) is positioned in the 90-degree area (area 1) and can sequentially revolve in a clockwise direction in the 0-degree area (area 2), -90-degree area (area 3), and -180-degree area (area 4).

[0393] FIG. 17 illustrates the operation method of the power transmission unit shown in FIG. 14.

[0394] FIG. 17(a) illustrates the motion conversion unit (300) rotated to the left, FIG. 17(b) illustrates the motion conversion unit (300) rotated to the center, and FIG. 17(c) illustrates the motion conversion unit (300) rotated to the right.

[0395] The above motion conversion unit (300) may include a rotary connector (310) connected to the eccentric shaft (222) and an extension shaft (320) extending downward from the end of the rotary connector (310).

[0396] The above motion transmission unit (400) can be coupled to the outer surface or lower end of the extension shaft (320) and coupled to the connecting unit (500).

[0397] The rotary connector (310) may be connected to the eccentric shaft (222) at one end or in an area adjacent to one end, and the other end may be provided to extend the extension shaft (320), and the length from one end to the other end of the rotary connector (310) may be longer than the width. By doing so, the angle at which the rotary connector (310) rotates the extension shaft (320) can be further expanded.

[0398] The above-mentioned rotary connector (310) may further include an eccentric hole (330) formed longitudinally at one end or in an area adjacent to the one end. Here, the longitudinal direction can be defined as the direction from one end to the other end of the rotary connector (410).

[0399] The eccentric hole (330) may be provided so that the eccentric shaft (222) is inserted or passes through it. The width of the eccentric hole (330) may be equal to or greater than the diameter of the eccentric shaft (222), and the length of the eccentric hole (330) may be longer than the width of the eccentric hole (330). The length of the eccentric hole (330) may be provided to be equal to or greater than the diameter of the eccentric shaft (222) rotating around the center of rotation of the transmission pulley (232). Thus, even when the eccentric shaft (222) is inserted or passes through the eccentric hole (330), it can rotate around the center of rotation of the transmission pulley (232) for more than one turn without being obstructed by the eccentric hole (330).

[0400] Referring to FIG. 17(a), when the eccentric shaft (222) rotates from 90 degrees to 0 degrees relative to FIG. 17 and rotates from area 1 to area 2, the eccentric shaft (222) moves from one end of the eccentric hole (330) to the center, rotating the rotary connector (410) clockwise, and the extension shaft (320) can also rotate clockwise.

[0401] Referring to FIG. 17(b), when the eccentric shaft (222) is continuously rotated from 0 degrees to -90 degrees and rotated from area 2 to area 3, the eccentric shaft (222) moves from the center of the eccentric hole (330) to the other end, rotating the rotary connector (310) counterclockwise, and the extension shaft (320) can also rotate counterclockwise.

[0402] Referring to FIG. 17(c), when the eccentric shaft (222) is rotated further from -90 degrees to -180 degrees and rotated from area 3 to area 4, the eccentric shaft (222) moves back from the other end of the eccentric hole (330) to the center, causing the rotation connector (310) to rotate further counterclockwise, and the extension shaft (320) can also rotate further counterclockwise.

[0403] When the eccentric shaft (222) is further rotated, the eccentric shaft (222) moves from the center of the eccentric hole (330) to one end, and the rotation connector (310) changes its rotation direction to rotate clockwise, and the extension shaft (320) also changes its direction to rotate clockwise.

[0404] As a result, the eccentric shaft (222) continuously rotates in one direction and reciprocates between one end and the other end relative to the eccentric hole (330), and the rotating cannulator (310) rotates reciprocally in clockwise and counterclockwise directions by changing its displacement left and right according to the rotation of the eccentric shaft (222), and the extension shaft (320) can also rotate reciprocally in clockwise and counterclockwise directions.

[0405] As a result, the connecting part (500) coupled to the power transmission part (400) moves back and forth in the width direction, and the hanger part (600) can rotate back and forth in clockwise and counterclockwise directions to rotate the clothes hanger part (1000) back and forth.

[0406] When the above eccentric shaft (222) rotates once, the above-mentioned clothes hanger part (1000) including the above-mentioned rotary connector (310) can all rotate back and forth once.

[0407] FIG. 18 illustrates an example of the detailed structure of a moving hanger of the clothing processing device of the present invention.

[0408] The lower structure of the support plate (150) above may be the same as that of the previously described embodiment.

[0409] Additionally, the bearing (800) can be positioned at the lower part of the auxiliary support (720) and seated in the installation groove (716) provided at the upper part of the main support (710).

[0410] The main support member (710) may further include a seating space (717) that is recessed at the upper part of the extension body (712) to provide a space for the auxiliary support member (720) to be seated.

[0411] The above-mentioned seating space (717) can be formed between the support protrusions (713), and the portion of the extension body (712) that overlaps vertically with the connecting part (500) can have an effect similar to being protruded upward due to the seating space (717).

[0412] The support groove (717) may be formed at the lowest position in the extension body (712), and the seating space (717) may be formed higher than the support groove (717) and lower than the upper surface of the extension body (712).

[0413] The support projection (713) may be formed to protrude further upward than the upper surface of the extension body (712).

[0414] The above coupling body (711) may have an insertion groove (7111) formed on the inside in which at least a part of the transmission shaft (420) is inserted.

[0415] The insertion groove (7111) can be extended in the height direction from the upper surface or support groove (715) of the extension body (712) to the top of the coupling body (711).

[0416] The above-mentioned transmission unit (230) can be positioned at a location that overlaps in the height direction at either end of the above-mentioned main support unit (710).

[0417] Thus, the motion conversion unit (300) is connected to the transmission unit (230), and the motion transmission unit (400) can be connected to the motion conversion unit (300) and coupled to a connection unit (500) that can be placed at one end of the main support unit (710).

[0418] The above motion conversion unit (300) may include an extension shaft (320) extending downward from the rotation connector (410), and the extension shaft (320) may penetrate the support plate (150) or be positioned on the upper part of the support plate (150).

[0419] The transmission shaft (410) of the power transmission unit (400) may pass through the support plate (150) or be positioned below the support plate (150) and connected to the extension shaft (320).

[0420] The above transmission shaft (410) can be inserted into the main support part (710) and the shield part (900).

[0421] The extension shaft (320) may include a first shaft (321) extending downward from the end of the rotary connector (310), and a second shaft (322) coupled to the first shaft (321) and seated on the support plate (150) or coupled to the transmission shaft (420).

[0422] The extension shaft (320), the transmission shaft (410), and the reciprocating shaft (420) are configured to be connectable while separated, thereby reinforcing the overall rigidity and making it easier to install them on the support plate (150).

[0423] The above transmission shaft (410) may include a main body shaft (411) coupled to the extension shaft (320), a coupling shaft (412) coupled to the lower part of the main body shaft (411) to which the reciprocating shaft (420) is coupled, and a protruding ring (413) coupled to either the main body shaft (411) or the coupling shaft (412) or protruding to which the support plate (150) or support bearing (820) is seated.

[0424] The above reciprocating shaft (420), the above coupling shaft (412), and the main body shaft (411) can be manufactured in a modular manner together with the above shielding part (900) when the above hanger frame (700) is combined, and the above support plate (150), the above driving part (200), and the above motion conversion part (300) can be manufactured separately in a modular manner. Subsequently, the upper module and the lower module can be combined based on the support plate (150) to complete the moving hanger (100).

[0425] FIG. 19 illustrates another embodiment of the driving unit of the moving hanger of the present invention.

[0426] The configuration disposed at the lower part of the support plate (150) may be the same as the previously described embodiment, and only the configuration disposed at the upper part of the support plate (150), such as the driving unit (200) and the motion conversion unit (300), may be different.

[0427] As such, the moving hanger (100) of the present invention may be configured in any way as long as the connecting part (500) can be reciprocated on the hanger frame (710) extending in the width direction from below the upper surface of the support plate (150) or inner case (20) to reciprocate the hanger part (600).

[0428] However, below, a structure that can rotate the rotary rod (532) in a different way from the structure of the drive unit (200) is described.

[0429] The above driving unit (200) may include a horizontal motor (210) mounted on the support plate (150) and a rotating unit (220) configured to rotate on the horizontal motor.

[0430] The above-mentioned rotating part (220) may include a drive shaft (221) that rotates by a horizontal motor (210). The drive shaft (221) may be arranged in a horizontal direction or a front-rear direction.

[0431] The above-mentioned rotating part (220) may include a displacement shaft (222) that rotates at a certain radius by the above-mentioned drive shaft (221). The above-mentioned displacement shaft (222) may be configured to correspond to the aforementioned eccentric shaft (222).

[0432] The above-mentioned rotating part (220) includes a shaft support part (223) that connects the displacement shaft (222) to the transmission part (230) or a power shaft (240) that rotates by the transmission part (230).

[0433] The shaft support member (223) can form a rotational displacement capable of rotating the transmission member (230) or the power shaft (240) by a certain radius. One end of the displacement shaft (223) is coupled to the shaft support member (223), so that the one end can rotate along a certain radius.

[0434] The above motion conversion unit (300) may be coupled to the end of the shaft support unit (223). The motion conversion unit (300) may include a rotation rod (330) that fixes the height of the end of the shaft support unit (223) but allows left and right movement of the shaft support unit (223).

[0435] The above transmission unit (230) may include a transmission pulley (232) having a diameter much larger than that of the drive shaft (221), and a belt (233) connecting the transmission pulley (232) and the horizontal rotation shaft (222).

[0436] The power shaft (240) may be coupled to the rotational center of the transmission pulley (232), and the transmission pulley (232) and the power shaft (240) may be supported by a pulley support member (234) coupled to the support member (800).

[0437] The above pulley support (234) may be equipped with a bearing that rotatably supports the power shaft (240).

[0438] The pulley support member (234) may be provided in the shape of a tripod or the like that which is seated on the support member (800) and extends upward, the transmission pulley (232) may be positioned at the rear or front of the pulley support member (234), and the free end of the power shaft (240) may be positioned at the front or rear of the pulley support member (234).

[0439] FIG. 20 illustrates the detailed structure of the drive unit shown in FIG. 19.

[0440] The horizontal motor (212) may be provided to rotate the horizontal rotation axis (221).

[0441] A power pulley (231) can be coupled to the horizontal rotation shaft (221) to rotate the belt (233) more smoothly and prevent the belt (233) from coming off.

[0442] The power shaft (240) is coupled to the transmission pulley (232) and can be supported by penetrating the pulley support (234).

[0443] The above power shaft (240) and the above horizontal rotation shaft (221) can be arranged side by side.

[0444] The above power shaft (240) can be coupled to one side off-center from the center of the shaft support (223).

[0445] The shaft support member (223) may be provided to be further extended in a direction away from the part to which the power shaft (240) is connected, and the displacement shaft (222) may have one end connected to a surface of the shaft support member (223) that is spaced far from the power shaft (240).

[0446] Thus, the shaft support member (223) may be configured such that one side to which the displacement shaft (222) is coupled rotates along a certain radius relative to the power shaft (240), and one end of the displacement shaft (222) may be configured to rotate along a certain radius relative to the power shaft (240).

[0447] The shaft support member (223) may include a shaft body (2231) having one side coupled to the power shaft (240) and the other side coupled to one end of the displacement shaft (222), and a center body (2231) that couples the shaft body (2232) to the power shaft (240). The center body (2231) may be positioned spaced apart from the center of gravity or center of length of the shaft body (2232).

[0448] The above displacement shaft (222) may include a displacement body (2221) extending from the shaft support (223) to the rotation rod (330), and a displacement end (2222) coupled from the displacement body (2221) to the rotation rod (330).

[0449] The above-mentioned rotating rod (330) may include a rod shaft (333) that extends vertically from the support plate (150) and is coupled to or extends to the transmission shaft (410), a displacement fixing part (332) that extends upward from the rod shaft (333) and is configured to reciprocate left and right and is coupled to the displacement end (2222), and a fastening member (331) that prevents the displacement end (2222) from detaching from the displacement fixing part (332).

[0450] FIG. 21 illustrates the operation method of the moving hanger shown in FIG. 19.

[0451] When the power shaft (240) rotates, the center body (2231) is configured to rotate, and the shaft body (2231) is configured to rotate with respect to the center body (2231).

[0452] The displacement shaft (221) can be connected at one end (2223) to a position spaced apart from the center body (2231) toward either end of the shaft body (2231).

[0453] When the distance between the above-mentioned end (2223) and the above-mentioned center body (2231) is the first radius (R), the above-mentioned end (2223) can rotate along the circle drawn by the first radius (R) and perform rotational motion.

[0454] The above-mentioned rotary rod (330) is configured to fix the position and height of the other end (2221) of the displacement axis (221). At this time, when one end (2223) of the displacement axis (221) moves along the first radius (R), the other end (2221) of the displacement axis moves back and forth, and the rotary rod (330) can move back and forth.

[0455] As a result, the rotary rod (330) can convert the rotational motion of the driving unit (200) in a certain direction into left-right reciprocating motion, and the rotary rod (330) can reciprocate the motion transmission unit (400).

[0456] FIG. 22 illustrates another embodiment of the moving hanger drive unit of the present invention.

[0457] The above moving hanger (100) may have the same structure and principle as the driving unit (200) and the structure and principle of the motion conversion unit (300), motion transmission unit (400), and connecting unit (500) as the above-described embodiment.

[0458] However, the above motion transmission unit (400) may be coupled to the above motion conversion unit (300) and configured to reciprocate.

[0459] The above motion conversion unit (300) may include a rod portion (340) that rotates with one end connected to the eccentric shaft (222), and an additional rod portion (360) that has one end connected to the motion transmission unit (400) and the other end connected to the other end of the rod portion (340).

[0460] The rod portion (340) coupled to the above eccentric shaft (222) can be defined as a power rod portion (340) because it receives power, and the additional rod portion (360) can be defined as a rotation rod portion (360) because it rotates the above motion transmission portion (400).

[0461] The above power rod part (340) and the above rotation rod part (360) can move like a four-bar linkage.

[0462] Meanwhile, the above-mentioned driving unit (200) may be provided with the same structure and principle as the driving unit (200) of FIG. 17.

[0463] The above connecting part (500) and the above hanger part (600) may be positioned below the support plate (150) and above the upper surface of the inner case (20).

[0464] The above eccentric shaft (222) may be provided to rotate by being coupled to the transmission pulley (232) at a portion spaced apart from the rotation center of the transmission pulley (232).

[0465] The additional rod portion (360) may be provided to rotate the motion transmission portion (400) located at the end in order to secure the rotational length of the power rod portion (340).

[0466] The power rod portion (340) includes one end (342) rotatably coupled to the eccentric shaft (222), another end (343) coupled to the rotating rod portion (360), and a power rod body (341) connecting them.

[0467] The above-mentioned rotating rod portion (360) may include one end (362) that is rotatably coupled to the other end (343) of the power rod portion, the other end (363) that is configured to rotate the rotational coupling shaft (370), and a rotating rod body (361) connecting the two.

[0468] FIG. 23 illustrates the operating principle of the moving hanger of FIG. 22.

[0469] The length (a2) of the power rod body (341) may be provided to be longer than the radius of rotation (a1) of the eccentric shaft (222). The length (a3) ​​of the rotating rod body (361) may be set to be shorter than the length (a2) of the power rod body (341). The length (a3) ​​of the rotating rod body (361) may be provided to be longer than the radius of rotation (a1) of the eccentric shaft (222).

[0470] When the above-mentioned rotating shaft (210) rotates, the above-mentioned eccentric shaft (222) rotates continuously. One end (342) of the above-mentioned power rod part (340) rotates continuously together with the above-mentioned eccentric shaft (222).

[0471] However, the other end (343) of the power rod part (340) is configured to reciprocate within a certain range (d) and cannot be configured to rotate completely 360 degrees due to the length of the power rod body (341) and the fact that the other end (343) is coupled to the rotating rod part (360).

[0472] One end (362) of the above-mentioned rotating rod portion (360) can be reciprocated at a certain angle (d) together with the other end (343) of the above-mentioned power rod portion (340).

[0473] FIG. 24 illustrates the operation process of the moving hanger of FIG. 22.

[0474] Referring to FIG. 24(a), the eccentric shaft (222) on the power shaft (240) can be positioned at the furthest position from the rotary coupling shaft (370).

[0475] As a result, the power rod portion (340) is coupled to the eccentric shaft (222) and can pull the rotation rod portion (360). Thus, the motion transmission portion (400) can rotate in a counterclockwise direction.

[0476] Referring to FIG. 24(b), when the drive unit (210) rotates, the eccentric shaft (222) can be positioned closest to the motion transmission unit (400). As a result, the power rod unit (340) can be pushed in the direction where the rotational rod unit (360) is located, and the power rod unit (340) can push the rotational rod unit (360) away from the eccentric shaft (222). Thus, the motion transmission unit (400) can rotate clockwise.

[0477] If the above eccentric shaft (222) rotates continuously in one direction, the above process can be repeated.

[0478] Consequently, the rotating rod portion (360) can reciprocate the motion transmission portion (400) like a handle or lever to rotate it by a certain angle (d). When the motion transmission portion (400) reciprocates, all hanger portions (600) can reciprocate, and the clothing mounted on the clothes hanger portion (1000) can also reciprocate.

[0479] Additionally, the driving unit (200), the motion transmission unit (400), and the connecting unit (500) of the present invention are provided with a rack and pinion structure, such that the connecting unit (500) is provided as a rack and at least one of the driving unit (200) and the motion transmission unit (400) is provided as a pinion structure, so that the connecting unit (500) can be provided to reciprocate within the main support unit (710).

[0480] The above hanger part (600) may also be provided with a gear structure in which the outer surface meshes with the connecting part (500), so that it reciprocates when the connecting part (500) moves back and forth.

[0481] The present invention may be modified and implemented in various forms, and its scope of rights is not limited to the embodiments described above. Therefore, if a modified embodiment includes the components of the claims of the present invention, it should be considered to fall within the scope of rights of the present invention.

Claims

1. Cabinet; An inner case providing a receiving space for clothing to be placed inside the cabinet; A machine room that supplies one or more of steam and air to the above-mentioned receiving space; A moving hanger configured to support the garment inside the aforementioned receiving space and to shake the garment; The above moving hanger is A hanger frame including a support body positioned in the width direction or front-rear direction of the inner case; A plurality of hanger sections arranged along the extension direction of the support body and on which the clothing is mounted; A connecting part provided to connect all of the above-mentioned plurality of hanger parts; A driving unit configured to rotate an eccentric shaft rotating along a certain radius in one direction; A motion conversion unit connected to the above eccentric shaft and converting the rotational motion of the above eccentric shaft into reciprocating motion; A motion transmission unit coupled to or extended from the motion conversion unit and configured to reciprocate the connection unit; comprising A clothing processing device characterized in that the support body, the hanger part, and the connecting part are disposed inside the receiving space.

2. In Paragraph 1, A clothing processing device characterized in that the above-mentioned driving unit is positioned outside the above-mentioned receiving space.

3. In Paragraph 2, A clothing processing device characterized in that at least a portion of the motion conversion unit is positioned outside the receiving space.

4. In Paragraph 3, A clothing processing device characterized in that at least a portion of the above-mentioned motion transmission unit is disposed within the above-mentioned receiving space.

5. In Paragraph 4, A clothing processing device characterized in that the above-mentioned motion transmission unit and the above-mentioned motion conversion unit are formed integrally.

6. In Paragraph 1, The above hanger frame includes extension bodies that extend from both ends of the support body and fix the support body to the upper surface of the inner case. A clothing processing device characterized in that at least a portion of the above-mentioned extension body is disposed inside a receiving space.

7. In Paragraph 6, A clothing processing device characterized in that the support body and the extension body are formed integrally.

8. In Paragraph 1, It further includes a support frame coupled to the upper part of the inner case and supporting the moving hanger, and A clothing processing device characterized in that the support body, the hanger part, and the connecting part are positioned below the support frame.

9. In Paragraph 8, A clothing processing device characterized in that at least a part of the motion conversion unit and the driving unit are positioned above the support frame.

10. In Paragraph 8, A clothing processing device characterized by the above motion transmission unit including a transmission shaft that transmits power transmitted to the motion conversion unit through the support frame to the connection unit.

11. In Paragraph 10, The above moving hanger is A clothing processing device characterized by further including a transmission bearing coupled to the support frame and rotatably supporting the transmission shaft.

12. In Paragraph 11, A clothing processing device characterized by the above-mentioned transmission shaft further including a seating ring that protrudes from or is coupled to the outer surface and is seated on the transmission bearing.

13. In Paragraph 1, A clothing processing device characterized by the above-described hanger being seated on the upper part of the above-described support body and arranged to be reciprocally rotatable.

14. In Paragraph 13, The above connecting part A clothing processing device characterized by being positioned at a location lower than the upper surface of the hanger part and higher than the upper surface of the hanger frame.

15. In Paragraph 14, The above hanger A hanger body in which a clothes hanger portion on which the above-mentioned clothing is mounted is detachably fixed, and It includes a hanger shaft that extends from the lower part of the hanger body and is seated on the hanger frame, and A clothing processing device characterized by the above-mentioned connecting part being connected to one side of the hanger body or the hanger shaft.

16. Cabinet; An inner case providing a receiving space for clothing to be placed inside the cabinet; A machine room that supplies one or more of steam and air to the above-mentioned receiving space; A moving hanger configured to support the garment inside the aforementioned receiving space and to shake the garment; The above moving hanger is A hanger frame including a support body positioned in the width direction or front-rear direction of the inner case; A plurality of hanger sections arranged along the extension direction of the support body and on which the clothing is mounted; A connecting part provided to connect all of the above-mentioned plurality of hanger parts; A driving unit configured to rotate an eccentric shaft rotating along a certain radius in one direction; A motion conversion unit connected to the above eccentric shaft and converting the rotational motion of the above eccentric shaft into reciprocating motion; A motion transmission unit coupled to or extended from the motion conversion unit and configured to reciprocate the connection unit; comprising The above-mentioned hanger part includes a mounting groove on the upper part in which a hook of a clothes hanger on which the garment is mounted is detachably seated. The above driving unit and the above motion transmission unit are positioned above the above seating groove, and A clothing processing device characterized in that the above connecting part is connected to the hanger part at a lower position than the above seating groove.

17. In Paragraph 16, The above seating groove is The above-mentioned hanger part is provided to extend in the diametrical direction and be convex upward, A clothing processing device characterized in that the above-mentioned connecting part is positioned below the lowest end of the above-mentioned seating groove.

18. In Paragraph 16, The above support body is positioned below the above hanger part, and A clothing processing device characterized in that the above-mentioned connecting part is positioned lower than the seating groove and higher than the support body.

19. Cabinet; An inner case providing a receiving space for clothing to be placed inside the cabinet; A machine room that supplies one or more of steam and air to the above-mentioned receiving space; A moving hanger configured to support the garment inside the aforementioned receiving space and to shake the garment; The above moving hanger is A hanger frame including a support body positioned in the width direction or front-rear direction of the inner case; A plurality of hanger sections arranged along the extension direction of the support body and on which the clothing is mounted; A connecting part provided to connect all of the above-mentioned plurality of hanger parts; A drive unit including a drive shaft that rotates in one direction; A motion conversion unit including an extension shaft configured to receive power from the above-mentioned drive shaft and reciprocate; A motion transmission unit configured to be coupled to or extended by the above extension shaft to reciprocate the above connection part; comprising A clothing processing device characterized in that the support body, the hanger part, and the connecting part are disposed inside the receiving space.

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