KR101989948B1 - Clothing processing apparatus - Google Patents

Abstract

The present invention provides an apparatus for clothing processing, which comprises: a first housing module (210) in which a first space (S1) is filled with a deodorizing solution, and an object is immersed in the filled deodorizing solution; a processing module which hits the object immersed into the first housing module (210) to accelerate deodorization of the object; and a second housing module (220) in which the first housing module (210) is disposed in a second space (S2) and the object to be processed is disposed in a third space, a remaining space, other than the first housing module (210) to be immersed into the deodorizing solution when filled with the deodorizing solution. The first housing module (210) includes an outer wall (211), a partition wall dividing the inner side of the outer wall (211) and a guide module disposed at an inner corner of the outer wall (211). The processing module directly or indirectly hits the object guided and immersed by the guide module. Accordingly, provided is an apparatus for clothing processing, which can efficiently perform clothing processing of a good quality and save costs for clothing processing, and clothing processed thereby.

Description

{CLOTHING PROCESSING APPARATUS}

The present invention relates to a garment processing means and a garment processed thereby, and more particularly, to a garment processing means capable of performing efficient and high-quality garment processing and reducing the cost of the garment, It is about clothes.

Apparel products are dominated by highly functional fibers. Quick-drying water, especially antibacterial and deodorant fibers are becoming popular. In modern people enjoying well-being, simple clothes that simply absorb sweat and discharge, clothes with antibacterial and deodorizing function are widely used. However, in spite of this tendency, there is a problem that the efficiency and the quality are deteriorated in the processing of a large amount of clothes (for example, deodorization). In addition, when a small contractor or an individual intends to perform such a process, efficiency and quality are significantly lowered, and the cost of operation is considerably increased, resulting in poor business performance of the garment business and difficulty in achieving the purpose of the individual garment processing. Therefore, there is a disadvantage in that there is no garment processing means that is efficient and easy to handle as well as capable of reducing the cost of garment processing.

Korean Patent No. 10-0206721

It is an object of the present invention to provide a garment processing means capable of performing efficient and high-quality garment processing and reducing the expense of cost of the garment, and a garment processed thereby.

The present invention relates to a first housing module (210) in which a deodorant liquid is filled in a first space (S1) and the object is immersed in a filled deodorant liquid; A processing module for hitting an object to be dipped in the first housing module 210 to accelerate the deodorization process of the object; And the first housing module 210 is located in the second space S2 and the object to be processed is placed in the third space which is the remaining space with the first housing module 210, Wherein the first housing module 210 includes an outer wall 211, a partition wall that divides the inner wall of the outer wall 211, And a guide module located at an inner edge of the wall 211, wherein the processing module is guided through the guide module and strikes an object to be immersed directly or indirectly.

Industrial Applicability According to the present invention, it is possible to provide an apparel processing means capable of performing efficient and high-quality apparel processing and reducing the expense of the cost of the apparel, and the processed apparel.

1 is a schematic view showing a garment processing means according to an embodiment of the present invention.
FIG. 2 is a view showing a part of the configurations according to FIG.
3 is a schematic view showing a garment processing means according to another embodiment of the present invention.
FIG. 4 is a view showing a part of the configurations according to FIG.
FIGS. 5-7 illustrate garments that are processed through garment processing means according to one embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
1 is a schematic view showing a garment processing means according to an embodiment of the present invention. 2 is a view showing a part of the configurations according to FIG. 3 is a schematic view showing a garment processing means according to another embodiment of the present invention.
1 to 3, the garment processing means includes a first housing module 210 in which a deodorizing liquid is filled in a first space S1, and an object is immersed in a filled deodorizing liquid; A processing module for hitting an object to be dipped in the first housing module 210 to accelerate the deodorization process of the object; And the first housing module 210 is located in the second space S2 and the object to be processed is placed in the third space which is the remaining space with the first housing module 210, And the second housing module 220 is immersed in the liquid.
The first housing module 210 includes an outer wall 211, a partition wall for partitioning the outer wall 211 and a guide module located at an inner corner of the outer wall 211. The processing module is guided through the guide module and directly or indirectly hits an object to be immersed. Wherein the partition wall includes a first partition wall body 212a for partitioning the inside of the outer wall body 211 and a second partition wall body 212b for partitioning the inside of the outer wall body 211, Is partitioned into a first partition space DS1 at one side, a second partition space DS2 at the middle side, and a third partition space DS3 at the other side through the partition wall 212a and the second partition wall body 212b.
The processing module includes a first processing part 231 driven and retracted in the first compartment space DS1 of the first housing module 210 via the second housing module 220, A second processing unit 232 driven and retracted in the second compartment space DS2 of the first housing module 210 via the first housing module 220 and the second housing unit 220 via the second housing module 220, And a third processing portion 233 driven and retracted in the second compartment space DS2 of the housing module 210. [ The first processing unit 231 includes a first flow bar 231a for transmitting a forward and backward driving force and a second flow bar 231b disposed at an end of the first flow bar 231a and positioned in the first compartment space DS1, A first fluid 231b provided on both sides of the first fluid 231b and protruding and retracting between the inside and the outside of the first fluid 231b; And a first sub-fluid 231c for performing a forward / backward motion and an ultrasonic vibration with respect to the direction of the fluid.
The third processing unit 233 includes a third moving bar 233a for transmitting the advancing / retreating driving force and a third moving bar 233b disposed at the end of the third moving bar 233a and positioned in the third compartment space DS3, The third fluid body 331b provided on both sides of the third fluid body 331b and protruding and retracting between the inside and the outside of the third fluid body and the protruding and retreating operation between the third fluid body 331b and the second partition wall body 212b, And a third sub-fluid 331c for performing a forward / backward motion and an ultrasonic vibration with respect to the direction of the fluid.
The guide module includes a first upper guide portion UG1 positioned on the upper portion of the first sub-fluid 231c and tapering in a downward diagonal direction from above, and a second upper guide portion UG2 positioned below the first sub- And a first lower guide part DG1 tapered in an upward diagonal direction, and the first sub-fluid 231c is guided by the first upper guide part UG1 and the first lower guide part DG1, And is advanced while being pressed toward the first fluid 231b. The first sub-fluid 231c is provided to have an elastic restoring force externally from the first fluid 231b.
The first upper guide portion UG1 includes a first upper base portion UB1 provided in the outer wall 211 and a second upper base portion UB2 tapered from the first upper base portion UB1, The tapered portion T11 includes a pair of the first 1-1 pieces UP11 and the first 1-2 piece UP12, Lt; RTI ID = 0.0 > 1 < / RTI >
The first downward guide portion DG1 includes a first lower base portion DB1 provided in the outer wall 211 and a second lower base portion DB1 tapered from the first lower base portion DB1, And the first and second tapered portions T12 and T12 are separated from each other by a pair of the first and third parts DP11 and DP12, Lt; RTI ID = 0.0 > 1-2 < / RTI >
The first upper upper base portion UB1 includes a first upper driving lever UB11 and a second upper upper driving lever UB12, (UB11) and a first upward driving part (UB13) for generating a driving force for a first-type upper driving part (UB12) The -2 upward driving unit UB12 is operated in the first to third separation mode which are spaced apart from each other based on the driving of the first upper driving unit UB13.
The first lower base portion DB1 includes a first downward driving piece DB11 and a second downward driving piece DB12, And a first downward driving part DB13 for generating a driving force for the first and second downward driving parts DB11 and DB12, (DB12) are operated in the first to fourth separation mode, which are spaced apart from each other based on the driving of the first downward driving unit DB13.
The guide module includes a second upper guide portion UG2 positioned on the upper portion of the third sub-fluid 331c and tapering in a downward diagonal direction from above, and a second upper guide portion UG2 positioned on the lower portion of the third sub- And the second lower guide portion DG2 tapers in an upward diagonal direction from the first lower guide portion UG2 and the second lower guide portion DG2, And is advanced while being pressed toward the third fluid 331b side. The third sub-fluid 331c is provided to have an elastic restoring force externally from the third fluid 331b.
The second upper guide portion UG2 includes a second upper base portion UB2 provided in the outer wall 211 and a second upper upper base portion UB2 tapered from the second upper base portion UB2, The second-1 tapered portion UP2 includes a pair of second-first-portion UP21 and a second-second-portion UP22, The second downward guide unit DG2 is operated in a second downward base unit DB2 provided in the outer wall body 211 and the second downward base unit DB2 is operated in the second downward base unit DB2, And a second 2-2 tapered portion T22 that tapers from the second sub-fluidic portion 331c and guides the third sub-fluid 331c. The second -2 tapered portion T22 includes a pair of second 2-3 DP 21 And is operated in the 2-2 flaring mode separated from each other by the second to fourth digits DP22.
The second upper upper base portion UB2 includes a second upper first driving piece UB21 and a second upper second driving piece UB22, And a second upper driving part UB23 for generating a driving force for the second upper driving part UB22, wherein the second upper driving part UB21 and the second upper driving part UB23, And the part UB22 is operated in the second to third spacing mode which is spaced apart from each other based on the driving of the second upper driving part UB23.
The second lower-side base part DB2 includes a second-first downward-driving part DB21, a second-second downward-driving part DB22, and a second- And a second downward driving part DB23 for generating a driving force for the second downward driving part DB22 and the second downward driving part DB2, The second downward driving unit DB22 is operated in the second-fourth separation mode, which is spaced apart from each other based on the driving of the second downward driving unit DB23.
The second processed portion 232 includes a second moving bar 232a for transmitting the advancing and retreating driving force and a second moving bar 232b provided at the end of the second moving bar 232a and positioned in the second compartment space DS2, And the second processed portion 232 is provided on the upper side of the second compartment space DS2 formed by the first partition wall body 212a and the second partition wall body 212b, And the movable part MP and the pressing part PP are respectively provided on the first and second partition walls 212a and 212b corresponding to both sides of the second fluid body 232b, A pressurizing module PM is provided. The pressing portion PP of the pressing module PM presses both sides of the second fluid body 232b with a predetermined pressing force with respect to the second fluid body 232b so as to be inserted into the second compartment space DS2 Limit the degree of entry.
The second housing module 220 includes a plurality of inner wall portions 221 flowing around the first housing module 210 and a plurality of inner wall portions 221 surrounding the inner wall portions 221, And an outer wall portion 222 having a plurality of driving portions for guiding and flowing. The inner wall body 221 includes a first inner wall 221a, a second inner wall 221b adjacent to the first inner wall 221a, a third inner wall 221b facing the first inner wall 221a, A wall 221c and a fourth inner wall 221d opposed to the second inner wall 221b and a third inner wall 221d located in the longitudinal direction between the first inner wall 221a and the third inner wall 221c A fifth inner wall 221e and a sixth inner wall 221f located adjacent to the fifth inner wall 221e and positioned longitudinally between the first inner wall 221a and the third inner wall 221c, A seventh inner wall 221g positioned between the second inner wall 221b and the fourth inner wall 221d in a longitudinal direction and a third inner wall 221g positioned between the second inner wall 221b and the fourth inner wall 221d, And an eighth inner wall 221h that is located between the first inner wall 221d and the second inner wall 221g and is adjacent to the seventh inner wall 221g.
The driving unit includes a first driving unit 232a1, a second driving unit 232a2 adjacent to the first driving unit 232a1, a third driving unit 232a3 facing the first driving unit 232a1, A fifth driving unit 232a5 positioned between the first driving unit 232a1 and the second driving unit 232a2 and a fourth driving unit 232a3 adjacent to the third driving unit 232a3, A sixth driver 232a6 positioned between the first driver 232a1 and the fourth driver 232a4 and a seventh driver 232a7 positioned between the first driver 232a1 and the third driver 232a3, And an eighth driving unit 232a8 positioned between the driving unit 232a2 and the fourth driving unit 232a4.
The first inner wall 221a is located between the first driving part 232a1 and the fifth driving part 232a5 and flows back and forth in the second space S2, The third inner wall 221c is positioned between the fifth driving unit 232a5 and the second driving unit 232a2 and is positioned between the third driving unit 232a3 and the sixth driving unit 232a6 Flow backward and forward. The fourth inner wall 221d is positioned between the sixth driving unit 232a6 and the fourth driving unit 232a4 and moves forward and backward while the fifth inner wall 221e moves between the first driving unit 232a1 and the fourth driving unit 232a4. And is moved between the seventh driving portions 232a7.
The sixth inner wall 221f is positioned between the seventh driving unit 232a7 and the third driving unit 232a3 and moves forward and backward while the seventh inner wall 221g moves between the second driving unit 232a2 and the third driving unit 232a2. The eighth inner wall 221h is located between the eighth driving unit 232a8 and the fourth driving unit 232a4 and is moved forward and backward.
3 is a schematic view showing a garment processing means according to another embodiment of the present invention. FIG. 4 is a view showing a part of the configurations according to FIG. Hereinafter, the description will be focused on the technical features. 3 to 4, the first partition wall body 212a has a first compartment body 212a1 and a first compartment body 212a1 coupled to both ends of the first compartment body 212a1, A pair of first flexible walls 212a2 connected to the inner walls of the first partition wall 212a1 and a pair of first flexible walls 212a2 coupled to the inner wall of the first partition wall 212a2, The area of the second compartment space S2 is adjusted.
The first partition body 212a1 generates ultrasonic vibration on the first variable wall body 212a2 and the first variable wall body 212a2 is provided on the outer circumferential surface along the longitudinal direction in a large number, And a fixed first contact body (TD1) for applying ultrasonic vibration to an object based on the ultrasonic vibration of the first contact body (212a1). A plurality of second contact members (TD1) disposed between the first contact bodies (TD1) and tilted in a constant direction, the second contact bodies being in the form of brushes, which apply ultrasonic vibration to the objects in a line contact with the object based on the ultrasonic vibration of the first compartment body TD2.
The second partition wall body 212b includes a second compartment body 212b1 and a pair of second compartment bodies 212b1 and 212b2 coupled to opposite ends of the second compartment body 212b1, The second variable wall 212b2 is formed in the second partition wall 212b2 so that the second variable wall 212b2 can be varied from the second partition wall 212b1 and the area of the second partition space S2 and the third partition space S3 The second partition body 212b1 generates ultrasonic vibration on the second variable wall body 212b2 and the second variable wall bodies 212b2 are provided on the outer circumferential surface along the length direction, And a fixed third contactor TD3 for applying ultrasonic vibration to the object based on the ultrasonic vibration of the second deformable wall 212b2 are provided on the third contact member TD3. The ultrasonic vibration of the second compartment body 212b1 is brought into line contact with the object based on the ultrasonic vibration, (In the form of a brush) is provided.
5 to 7 are diagrams showing clothes (for example, clothes having an anti-lifting structure of the pants overlapping portion) to be processed through the clothing processing means according to an embodiment of the present invention. 5 to 7, in the overlapping region P where the zipper 1 is located, the first and second magic portions P are formed in order to prevent the overlapping region P, which is generated when the zipper 1 is filled, The front waist portion with the zipper 1 as a reference is formed at a predetermined interval so that the tapes 10a and 10a 'are adhered to each other and the first and second endotopes 100 and 100' The outer surface of the end portion of the first endothelial part 100 and the inner surface of the end of the second endothelial part 100 'are adhered to each other so that the pants can be filled with the second wing parts 200 and 200' And a fifth magic tape 10c having a length in the longitudinal direction is formed on the outer surface of the second endothelium 100 ', and the third and fourth magic tapes 10b and 10b' A seventh magic tape 10d having a length in the longitudinal direction is formed on the outer surface of the first wing part 200, and on the end of the inner surface thereof, A sixth magic tape 10c 'in the longitudinal direction which is adhered to the formed fifth magic tape 10c to vary the waist size, and the inner edge of the second wing portion 200' The elastic tape 10d 'is adhered to the seventh elastic tape 10d formed on the second elastic tape 200, thereby changing the waist size.
One embodiment of the present invention is a method for preventing the lifting of the overlapping area P at the same time as filling the zipper 1 when the user fills the zipper 1 after wearing the pants, And first and second magic tapes 10a and 10a 'corresponding to each other are adhered to both ends. Then, the overlapping area P of the pants in which the zipper 1 is positioned from the adhesion of the first and second elastic tapes 10a and 10a 'will not be lifted. On the other hand, the first and second endotopes 100 and 100 'and the first and second wings 200 and 200' of the trousers, which are double-treated based on the zipper 1, The third and fourth elastic tapes 10b and 10b and 10b and 10b and 10b and 10b and 10b and 10b ' Respectively. At this time, the sixth magic tape 10c 'formed on the first wing part 200 is folded by the third and fourth magic tapes 10b and 10b' To the fifth magic tape 10c formed on the outer surface of the second magic tape 100 '.
When the eighth magic tape 10d 'formed on the second wing portion 200' is adhered to the seventh magic tape 10d formed on the outer surface of the first wing portion 200, The waist size of the pants varies from the overlapping of the parts 200 and 200 'so that the fixing can be firmly performed. That is, when the adhesive positions of the sixth and eighth elastic tapes 10c 'and 10d' formed on the inner surfaces of the first and second wings 200 and 200 'are changed, the wearer's waist size The size of the pants can be reduced or increased in the variable waist size. Further, since the strap is not used as in the prior art, it is possible to prevent the pressing of the waist portion due to the strap. FIG. 6 is a view showing an anti-flap structure of a shirt (or a southern) overlapping portion according to another embodiment of the present invention. As shown in FIG. 6, the overlapping portion Q of the front portion of the shirt, 9 and 10 are formed at predetermined intervals and the eleventh and twelfth magic tapes 40 and 40 'having different lengths without buttons are formed at the sleeves, The lifting phenomenon of the overlapping region Q occurring between the button and the button when the button 2 is folded on the front side can be prevented by adhesion of the ninth and tenth magic tapes 30 and 30 ' .
In addition, the length of the circumference of the waist shirt can be adjusted through the eleventh and twelfth elastic tapes 40 and 40 'having different lengths at the sleeve portion of the waistcoat so that even if the wrist circumference of the waist shirt is variable, So that they can respond. FIG. 7 is a view showing a lifting preventing structure of a jumper overlapping portion according to another embodiment of the present invention. As shown in FIG. 7, the overlapping portion R of the jumper front portion, The elastic tapes 50 and 50 'are formed at predetermined intervals so that the lifting phenomenon of the overlapping region R for covering the zipper 1 when the zipper 1 is filled after the jumper is put on, 14 can be prevented by adhesion of the elastic tapes 50 and 50 '. Of course, these garments are illustrative and are applicable to various kinds of clothes.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

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210: first housing module 211: outer wall
212a: first partition wall body 212b: second partition wall body
220: second housing module 231: first processing part
232: second machining portion 233: third machining portion

Claims (10)

A first housing module 210 in which a deodorant liquid is filled in a first space S1 and the object is immersed in a filled deodorant liquid;
A processing module for hitting an object to be dipped in the first housing module 210 to accelerate the deodorization process of the object; And
The first housing module 210 is located in the second space S2 and the object to be processed is placed in the third space which is the remaining space with the first housing module 210, And a second housing module (220)
The first housing module 210,
An outer wall 211,
A partition wall partitioning the inside of the outer wall body 211,
And a guide module located at an inner corner of the outer wall 211,
Wherein the processing module is guided through the guide module and directly or indirectly strikes an object to be immersed. The method according to claim 1,
The partition wall
A first partition wall body 212a for partitioning the inside of the outer wall body 211,
And a second partition wall body (212b) for partitioning the inside of the outer wall body (211)
The inner space is divided into a first partition space DS1 on one side, a second partition space DS2 on the middle side and a third partition space DS2 on the other side through the first partition wall 212a and the second partition wall 212b DS3)
The processing module includes:
A first processing section 231 driven and retracted in the first compartment space DS1 of the first housing module 210 via the second housing module 220,
A second machining portion 232 which is advanced and retreated in the second compartment space DS2 of the first housing module 210 via the second housing module 220,
And a third processing section (233) driven and retracted in the second compartment space (DS2) of the first housing module (210) via the second housing module (220)
The first processed portion 231 may be formed by,
A first flow bar 231a for transmitting a forward and backward driving force,
A first fluid 231b provided at an end of the first flow bar 231a and positioned in the first compartment space DS1 to perform a price,
A first sub-fluid 231c provided at both sides of the first fluid 231b and performing the forward and backward movement and the ultrasonic vibration from the first fluid 231b toward the first partition wall 212a,
The third machining portion 233 is formed by,
A third flow bar 233a for transmitting the forward and backward driving force,
A third fluid 331b provided at an end of the third flow bar 233a and positioned in the third compartment space DS3 to perform a price,
And a third sub fluid 331c provided on both sides of the third fluid 331b and performing the forward and backward movement and the ultrasonic vibration from the third fluid 331b toward the second partition wall 212b In garment processing means. The method of claim 2,
The guide module comprises:
A first upper guide part UG1 positioned above the first sub-fluid 231c and tapering in a downward diagonal direction from above,
And a first downward guide portion (DG1) positioned below the first sub-fluid (231c) and tapering in an upward diagonal direction from below,
And the first sub-fluid 231c is advanced while being pressed toward the first fluid 231b by the first upper guide UG1 and the first lower guide DG1. delete delete delete delete delete delete delete

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