KR102801590B1 - A method for manufacturing a microfiber mop for cleaning using recycled fibers and microfiber mob for cleaning manufactured thereby - Google Patents

Abstract

The present invention relates to a method for manufacturing a cleaning mop/cloth using recycled fibers, which enables the manufacture of a cleaning tool that not only reuses resources but also maximizes absorption rate and improves cleaning efficiency by using sustainable fibers (recycled fibers), and to a cleaning mop manufactured thereby, the method comprising: a first absorbent layer manufacturing step of manufacturing a first absorbent layer made of an eco-friendly nonwoven fabric using recycled materials; a cleaning surface forming step of forming a cleaning surface made of recycled ultrafine fibers and a scrub material at regular intervals along the upper surface of the first absorbent layer manufactured by the first absorbent layer manufacturing step; a second absorbent layer manufacturing step of manufacturing a second absorbent layer of ultrafine fiber fabric using recycled yarn; a bottom layer manufacturing step of manufacturing a bottom layer having a loop-shaped Velcro formed on the lower surface using recycled mono yarn; a lamination step of sequentially laminating the bottom layer, the second absorbent layer, and the first absorbent layer from the lower side; and a tape finishing step of manufacturing a cleaning ultrafine fiber mop by finishing along the edge of a laminate comprising the bottom layer, the second absorbent layer, and the first absorbent layer using a polytape made of recycled materials.

Description

Method for manufacturing a microfiber mop for cleaning using recycled fibers and microfiber mob for cleaning manufactured thereby

The present invention relates to a method for manufacturing an ultrafine fiber cleaning mop using recycled fibers, and to a ultrafine fiber cleaning mop manufactured thereby. More specifically, the present invention relates to a method for manufacturing an ultrafine fiber cleaning mop using recycled fibers, and to a ultrafine fiber cleaning mop manufactured thereby, which enables the manufacture of a cleaning tool in which cleaning mops/cloths, etc. are manufactured using sustainable fibers (recycled fibers), thereby maximizing absorption rate and improving cleaning efficiency as well as reusing resources.

Polyurethane fibers are used in various products by mixing with other fibers due to their excellent elasticity. Examples include, in particular, socks, swimwear, clothing, and hygiene products such as diapers. The demand is increasing every year, which also means an increase in the demand for raw materials such as polyols, isocyanates, and chain extenders such as diamines and diols.

Meanwhile, recently, as the depletion of oil resources and global warming have become serious problems, movements toward a sustainable society are becoming more active.

From a sustainability perspective, for example, production activities using bio-based raw materials that aim for carbon neutrality are a major means of achieving this.

In addition, as we become more affluent, the amount of waste and waste increases, and the lack of disposal facilities and treatment facilities, environmental pollution, etc. have become major problems for a long time. Therefore, responding to the 3Rs of waste generation suppression (reduction), proper reuse (reuse) of used products, etc., and final recycling can also be very effective means of realizing a sustainable society.

Meanwhile, the background technology described above is technical information that the inventor possessed for deriving the present invention or acquired during the process of deriving the present invention, and cannot necessarily be considered as publicly known technology disclosed to the general public prior to the application of the present invention.

Korean Patent Publication No. 10-2022-0037510 (Published on March 24, 2022)

One aspect of the present invention provides a method for manufacturing a cleaning mop/cloth using recycled fibers, which enables the manufacture of a cleaning tool that not only reuses resources but also maximizes absorption rate and improves cleaning efficiency by using sustainable fibers (recycled fibers), and a cleaning mop manufactured thereby.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

According to one embodiment of the present invention, a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers includes: a first absorbent layer manufacturing step of manufacturing a first absorbent layer made of an eco-friendly nonwoven fabric using recycled materials; a cleaning surface forming step of forming a cleaning surface made of recycled ultrafine fibers and a scrub material at regular intervals along an upper surface of the first absorbent layer manufactured by the first absorbent layer manufacturing step; a second absorbent layer manufacturing step of manufacturing a second absorbent layer of ultrafine fiber fabric using recycled yarn; a bottom layer manufacturing step of manufacturing a bottom layer having a loop-shaped Velcro formed on a bottom surface using recycled monofilament yarn; a lamination step of sequentially laminating the bottom layer, the second absorbent layer, and the first absorbent layer from the lower side; and a tape finishing step of manufacturing a cleaning ultrafine fiber mop by finishing along the edge of the laminated body including the bottom layer, the second absorbent layer, and the first absorbent layer using a polytape using recycled materials.

In one embodiment, the second absorbent layer may be made of a 0.5 denier microfiber fabric.

In one embodiment, the method for manufacturing a cleaning microfiber mop using recycled fibers according to one embodiment of the present invention may further include a label adding step of adding a label having a product description on one side of the lower surface of the bottom layer before the tape finishing step.

In one embodiment, the method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to one embodiment of the present invention may further include a tag adding step of adding a color tag manufactured with a color for distinguishing the intended use of the product to one side of the lower surface of the bottom layer before the tape finishing step.

In one embodiment, a method for manufacturing a cleaning ultrafine fiber mop using recycled fiber according to another embodiment of the present invention may further include an edge pressurizing step of alternately stacking edge pressurizing frames and the cleaning ultrafine fiber mops, and then pressurizing the edge pressurizing frame located at the top by lowering it using a hydraulic cylinder to pressurize each edge of the cleaning ultrafine fiber mop.

In one embodiment, the edge pressure frame may include: a "ㅁ" shaped frame body formed in a "ㅁ" shape corresponding to the shape of the edge of the cleaning ultra-fine fiber mop; a first frame mounting groove formed along a bottom surface of the "ㅁ" shaped frame body; a "ㅁ" shaped pressure frame formed in a "ㅁ" shape corresponding to the shape of the bottom surface of the "ㅁ" shaped frame body and mounted in the first frame mounting groove so that a lower portion thereof is exposed from the first frame mounting groove; a second frame mounting groove formed along an upper surface of the "ㅁ" shaped pressure frame so that a lower portion of another "ㅁ" shaped pressure frame installed in another "ㅁ" shaped frame body disposed on an upper side of the "ㅁ" shaped frame body can be mounted thereon; and four pressure buffer members installed at four respective corners of the first frame mounting groove to support upper portions of respective corners of the "ㅁ" shaped pressure frame mounted in the first frame mounting groove.

In one embodiment, the pressure buffer may include a mounting plate that protrudes upward from an upper side of a corner of the “ㅁ” shaped pressure frame; an upper mounting groove formed on an upper side of a corner of the first frame mounting groove opposite the mounting plate; a lower mounting groove formed on an upper side of the mounting plate opposite the upper mounting groove; and a frame support plate having an upper side mounted in the upper mounting groove and a lower side mounted in the lower mounting groove to support the mounting plate.

In one embodiment, the frame support may include: a first support plate portion that is seated in the upper seating groove and supports an upper surface of a corner of the first frame seating groove; a second support plate portion that is seated in the upper seating groove and supports the seating step while being spaced apart from the first support plate portion and facing the first support plate portion; a rotational connection bearing portion that is installed on a lower side of the first support plate portion; a rotational cover portion that is rotatably connected and installed to a lower side of the first support plate portion by the rotational connection bearing portion; and a cover support portion that is installed on an upper side of the second support plate portion and is interlocked and connected to an inner side of the rotational cover portion to support the rotational cover portion.

In one embodiment, the rotary cover part may include: a cover body formed in a cylindrical shape; a fastening head protruding from the upper end of the cover body corresponding to the shape of a fastening groove of the rotary connection bearing part so as to be fastened to the rotary connection bearing part; a support mounting groove formed so as to form an opening in the lower side of the cover body so that the cover support part can be inserted and formed so as to have an inner diameter corresponding to an outer diameter of the cover support part and extending in a vertical direction along the inner side of the cover body; a spiral line which is an imaginary line formed so as to extend in a spiral direction along the inner circumference of the support mounting groove; and a plurality of gear blocks which are installed in a row at regular intervals along the spiral line and form gear teeth along a shear exposed to the support mounting groove.

In one embodiment, the cover support may include a cylindrical shape having an outer diameter corresponding to the inner diameter of the support portion mounting groove, and fixedly installed on the upper end of the second support plate, and installed on the inner side of the support portion mounting groove to engage with the gear teeth of the gear block and connect and support the cover body; a rotational member installed upright and rotatably connected to the upper center of the second support plate, inserted into the inner side of the transmission member and connected and installed, and rotated by an external force transmitted from the rotational cover part via the transmission member; and a plurality of return members installed at regular intervals along the lower side of the rotational member from the upper end of the second support plate to prevent rotation of the rotational member and at the same time return the rotational member rotated by the external force to an original position.

In one embodiment, the transmission member comprises: a transmission body formed in a cylindrical shape having an outer diameter corresponding to an inner diameter of the support member mounting groove and fixedly installed on an upper end of the second support plate; a pillar mounting groove formed to extend in a vertical direction along the inner side of the transmission body while forming an opening in a lower portion of the transmission body so that the rotation member can be inserted and positioned, and an inner diameter corresponding to the outer diameter of the rotation member; a gear moving groove formed to extend in a spiral shape along the outer circumference of the transmission body so that the plurality of gear blocks can move as the plurality of gear blocks are all mounted and an external force is transmitted to the cover body at the same time; And it may include a transmission gear which is installed so as to be repeatedly rotatable while being spaced apart at regular intervals along the inner side of the transmission body while facing the gear movement groove, each end of which is exposed to the gear movement groove and connected to the gear teeth of the gear block by gear engagement, and each other end of which is exposed to the pillar mounting groove and connected to the rotation member by gear engagement.

In one embodiment, the rotating member may include: a rotating column formed in a cylindrical shape that is rotatably connected and installed upright at the center of the upper end of the second support plate, the cylindrical shape having an outer diameter corresponding to the inner diameter of the column mounting groove, and inserted and mounted in the column mounting groove; a meshing gear formed along the outer side of the rotating column so as to be connected and installed by meshing with each of the gear teeth of the plurality of transmission gears exposed through the column mounting groove; and a plurality of pillar support wings that are spaced apart at regular intervals along the lower side of the rotating column and are supported by the return member.

In one embodiment, the return member may include a support wing mounting groove formed in a recessed manner in an upper portion of the second support plate so that the column support wing can be mounted thereon, and formed in a recessed manner in an upper portion of the second support plate so that the rotational column can rotate only by a preset angle, corresponding to a movement trajectory of the column support wing when the rotational column rotates; a first wing support spring installed in a space on one side of the support wing mounting groove after the column support wing is mounted thereon and supporting one side of the column support wing; and a second wing support spring installed in a space on the other side of the support wing mounting groove after the column support wing is mounted thereon and supporting the other side of the column support wing.

According to one aspect of the present invention described above, by manufacturing a cleaning mop/cloth, etc. using sustainable fibers (recycled fibers), it is possible to manufacture a cleaning tool that not only reuses resources but also maximizes absorption rate and improves cleaning efficiency.

The effects of the present invention are not limited to the effects mentioned above, and various effects may be included within a range obvious to those skilled in the art from the contents described below.

FIG. 1 is a drawing schematically illustrating a configuration of a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to one embodiment of the present invention.
FIG. 2 is a drawing showing a cleaning ultrafine fiber mop using recycled fibers manufactured by a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to one embodiment of the present invention.
FIG. 3 is a drawing schematically illustrating a configuration of a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to another embodiment of the present invention.
Figures 4 to 6 are drawings showing a border pressure frame used in the present invention.
FIGS. 7 to 9 are drawings showing one embodiment of the frame support of FIG. 6.

The detailed description of the invention set forth below refers to the accompanying drawings which illustrate, by way of example, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention, while different from one another, are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention. It should also be understood that the positions or arrangements of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly so described. Like reference numerals in the drawings designate the same or similar functionality throughout the several aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

FIG. 1 is a drawing schematically illustrating a configuration of a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to one embodiment of the present invention.

Referring to FIG. 1, a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to one embodiment of the present invention first manufactures a first absorbent layer (11) made of an eco-friendly nonwoven fabric using recycled materials (S110).

Here, the first absorption layer (11) can have an absorption rate of 70 g/m2 to 11 g/m2.

A cleaning surface (12) composed of recycled ultrafine fibers and scrub material is formed at regular intervals along the upper surface of the first absorbent layer (11) manufactured by the first absorbent layer manufacturing step (S110) (S120).

A second absorbent layer (13) of ultrafine fiber fabric using recycled yarn is manufactured (S130).

In one embodiment, the second absorbent layer (13) may be made of a 0.5 denier microfiber fabric.

A bottom layer (14) is manufactured on which a loop-shaped Velcro (15) using recycled monofilament is formed on the bottom surface (S140).

Here, the loop-shaped Velcro (15) can be attached to the hook of the vacuum cleaner Velcro (Velco) to enable the user to use it easily.

The bottom layer (14), the second absorption layer (13), and the first absorption layer (11) are sequentially laminated from the lower side (S150).

A cleaning ultrafine fiber mop (10) is manufactured by finishing the edges of a laminate consisting of a bottom layer (14), a second absorbent layer (13), and a first absorbent layer (11) using a polytape (16) made of recycled materials (S160).

The method for manufacturing a cleaning ultrafine fiber mop using recycled fibers having the steps described above may further include a label addition step (not shown in the drawing for convenience of explanation) of adding a label (17) having a product description on one side of the lower surface of the bottom layer (14) after the tape finishing step (S160) described above and before the tape finishing step.

The method for manufacturing a cleaning ultrafine fiber mop using recycled fibers having the steps described above may further include a tag addition step (not shown in the drawing for convenience of explanation) of adding a color tag (18) made in a color for distinguishing the intended use of the product to one side of the lower surface of the bottom layer (14) before the tape finishing step.

The ultra-fine fiber cleaning mop (20) using recycled fibers manufactured by the method for manufacturing an ultra-fine fiber cleaning mop using recycled fibers having the steps described above can be manufactured as 1) a hygiene management, industrial ultra-fine fiber mop (mop) for floor cleaning used in public spaces such as hospitals and schools, 2) application of highly absorbent recycled ultra-fine fiber cleaning cotton fabric 3) application of hard fiber cleaning cotton fabric with the function of removing stains (scrubbing function) 4) application of recycled ultra-fine fiber absorbent layer with moisture discharge ability enabling wide-area cleaning 5) Velcro type that can be easily attached and detached in the form of a hook 6) product that can be washed 300 times at high temperature 7) cleaning cotton can be wiped off by wetting it with a disinfectant or water 8) bacteria pickup rate of 99% or higher 9) containing 60% or more recycled materials 10) application of a four-color system as a border finish or label type 11) cross-infection hygiene management by distinguishing cleaning areas by color 12) It can be equipped with functions such as obtaining GRS certification.

The method for manufacturing a cleaning ultrafine fiber mop using recycled fibers having the steps described above can enable the manufacturing of a cleaning tool that not only reuses resources but also maximizes absorption rate and improves cleaning efficiency by manufacturing a cleaning mop/cloth, etc. using sustainable fibers (recycled fibers).

FIG. 3 is a drawing schematically illustrating a configuration of a method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to another embodiment of the present invention.

Referring to FIG. 3, a method for manufacturing a cleaning ultrafine fiber mop using recycled fiber according to another embodiment of the present invention further includes an edge pressurizing step (S170) of alternately stacking edge pressurizing frames (20) and cleaning ultrafine fiber mops (10) as shown in FIGS. 4 and 5, and then pressurizing the edge pressurizing frame (20) located at the top by lowering it using a hydraulic cylinder (30) to pressurize each edge of the cleaning ultrafine fiber mop (10).

A method for manufacturing a cleaning ultrafine fiber mop using recycled fibers according to another embodiment of the invention having the steps described above can solve the shape imbalance of the cleaning ultrafine fiber mop (10) resulting from mass production of the cleaning ultrafine fiber mop (10) by pressurizing and manufacturing each cleaning ultrafine fiber mop (10) to a predetermined thickness and shape using a rim pressurizing frame (20).

Figures 4 to 6 are drawings showing a border pressure frame used in the present invention.

Referring to FIGS. 4 to 6, the edge pressure frame (20) includes a “ㅁ” shaped frame body (100), a first frame mounting groove (200), a “ㅁ” shaped pressure frame (300), a second frame mounting groove (400), and four pressure buffer parts (500).

The “ㅁ” shaped frame body (100) is formed in a “ㅁ” shape corresponding to the shape of the edge of the ultra-fine cleaning mop (10).

The first frame fixing home (200) is formed along the bottom surface of the “ㅁ” shaped frame body (100).

The “ㅁ” shaped pressurized frame (300) is formed in a “ㅁ” shape corresponding to the shape of the bottom surface of the “ㅁ” shaped frame body (100) and is seated in the first frame mounting groove (200) so that the lower portion is exposed from the first frame mounting groove (200).

The second frame fixing home (400) is formed along the upper surface of the “ㅁ”-shaped pressurizing frame (300) so that the lower part of another “ㅁ”-shaped pressurizing frame (300) installed on another “ㅁ”-shaped frame body (100) positioned on the upper side of the “ㅁ”-shaped frame body (100) can be fixed thereon.

Four pressurized buffer members (500) are installed at each of the four corners of the first frame mounting groove (200) to support the upper side of each corner of the “ㅁ” shaped pressurized frame (300) mounted in the first frame mounting groove (200).

In one embodiment, the pressurized buffer (500) may include a protruding mounting protrusion (510), an upper mounting groove (520), a lower mounting groove (530), and a frame support (700).

The anchoring jaw (510) is formed to protrude upward from the upper side of the corner of the “ㅁ” shaped pressurizing frame (300).

The upper mounting groove (520) is formed on the upper side of the corner of the first frame mounting groove (200) facing the mounting protrusion (510).

The lower mounting groove (530) is formed on the upper surface of the mounting protrusion (510) facing the upper mounting groove (520).

The frame support member (700) supports the mounting bracket (510) by having the upper part mounted in the upper mounting groove (520) and the lower part mounted in the lower mounting groove (530).

The edge pressurizing frame (20) having the configuration described above can solve the shape imbalance of the cleaning ultra-fine fiber mop (10) resulting from mass production of the cleaning ultra-fine fiber mop (10) by pressurizing and manufacturing each cleaning ultra-fine fiber mop (10) with a certain thickness and shape.

FIGS. 7 to 9 are drawings showing one embodiment of the frame support of FIG. 6.

Referring to FIGS. 7 to 9, the frame support member (700) includes a first support plate member (710), a second support plate member (720), a rotation connection bearing member (730), a rotation cover member (740), and a cover support member (750).

The first support plate part (710) is mounted on the upper mounting groove (520) to support the upper side of the corner of the first frame mounting groove (200), and a rotational connection bearing part (730) is installed on the lower surface.

The second support plate part (720) is spaced apart from the first support plate part (710) and faces the first support plate part (710) and is seated in the lower seating groove (530) to support the seating protrusion (510), and a cover support part (750) is connected and installed at the upper end.

The rotation connection bearing part (730) is installed on the lower side of the first support plate part (710) and is connected to the rotation cover part (740) so that it can rotate.

The rotation cover part (740) is rotatably connected and installed on the lower side of the first support plate part (710) by the rotation connection bearing part (730).

In one embodiment, the rotating cover portion (740) may include a cover body (741), a fastening head (742), a support mounting groove (743), and a plurality of gear blocks (745).

The cover body (741) is formed in a cylindrical shape and is configured with a fastening head (742), a support mounting groove (743), and a plurality of gear blocks (745).

The fastening head (742) is formed to protrude from the top of the cover body (741) corresponding to the shape of the fastening groove (731) of the rotating connection bearing part (730) so that it can be fastened to the rotating connection bearing part (730).

The support mounting groove (743) forms an opening in the lower side of the cover body (741) so that the cover support (750), i.e., the transfer body (7511), can be inserted and positioned so as to be rotatable, and is formed to extend in the up-and-down direction along the inner side of the cover body (741) while forming an inner diameter corresponding to the outer diameter of the cover support (750).

The spiral line (744) is formed as an imaginary line that extends in a spiral direction along the inner surface of the support mounting groove (743) so that a plurality of gear blocks (745) can be installed in a row.

A plurality of gear blocks (745) are installed in a row at regular intervals along a spiral line (744) and form gear teeth along a front end exposed to a support mounting groove (743) so that they can be engaged with a transmission gear (7514) by gear engagement.

The cover support member (750) is installed on the upper side of the second support play member (720) and is interlocked and connected to the inner side of the rotating cover member (740) to support the rotating cover member (740).

In one embodiment, the cover support (750) may include a transfer member (751), a rotation member (752), and a plurality of return members (753).

The transmission member (751) is formed in a cylindrical shape with an outer diameter corresponding to the inner diameter of the support mounting groove (743), is fixedly installed on the upper end of the second support plate (720), and is installed on the inner side of the support mounting groove (743) and then meshes with the gear teeth of the gear block (745) to support the cover body (741).

In one embodiment, the transmission member (751) may include a transmission body (7511), a pillar mounting groove (7512), a gear moving groove (7513), and a transmission gear (7514).

The transmission body (7511) is formed in a cylindrical shape with an outer diameter corresponding to the inner diameter of the support mounting groove (743) and is fixedly installed on the upper end (721) of the second support plate (720), and components such as a pillar mounting groove (7512), a gear moving groove (7513), and a transmission gear (7514) are installed.

The pillar mounting groove (7512) forms an opening in the lower side of the transmission body (7511) so that the rotation member (752) can be inserted and positioned, and is formed to extend in the vertical direction along the inner side of the transmission body (7511) while forming an inner diameter corresponding to the outer diameter of the rotation member (752).

The gear moving home (7513) is formed in a spiral shape along the outer surface of the transmission body (7511) corresponding to the shape of the spiral line (744) so that a plurality of gear blocks (745) can move as external force is transmitted to the cover body (741) while all of the gear blocks (745) are seated as shown in FIG. 9.

The transmission gears (7514) are installed so as to be repeatedly rotatable in a plurality of pieces while facing the gear movement groove (7513) and spaced apart at regular intervals along the inside of the transmission body (7511), and as illustrated in FIG. 9, each end is exposed to the gear movement groove (7513) and connected to the gear block (745) by gear engagement, and each other end is exposed to the pillar mounting groove (7512) and connected to the rotating member (752) by gear engagement.

The rotating member (752) is installed so as to be upright and rotatably connected to the upper center of the second support play member (720), is inserted into the inside of the transmission member (751), and is connected and installed, and is rotated by an external force transmitted from the rotation cover part (740) via the transmission member (751).

In one embodiment, the rotating member (752) may include a rotating column (7521), a biting gear (7522), and a plurality of column support wings (7523).

The rotary column (7521) is installed so as to be rotatably connected and erected at the upper center of the second support play member (720), and is supported by a plurality of column support wings (7523). However, it is formed in a cylindrical shape with an outer diameter corresponding to the inner diameter of the column mounting groove (7512) and is inserted and mounted in the column mounting groove (7512).

The interlocking gear (7522) is formed along the outer side of the rotating column (7521) so that it can be connected and installed by meshing with the respective gear teeth of a plurality of transmission gears (7514) exposed through the column mounting groove (7512).

A plurality of pillar support wings (7523) are installed at regular intervals along the lower side of the rotating pillar (7521) and are supported by the return member (753).

A plurality of return members (753) are installed at regular intervals along the lower side of the rotation member (752) from the upper side of the second support play member (720) to prevent rotation of the rotation member (752) and at the same time return the rotation member (752) rotated by an external force to its original position.

In one embodiment, the return member (753) may include a support wing mounting groove (7531), a first wing support spring (7532), and a second wing support spring (7533).

The support wing mounting groove (7531) is formed recessed in the upper end of the second support plate (720) so that the pillar support wing (7523) can be mounted thereon, but is formed recessed in the upper end of the second support plate (720) so that the rotational pillar (7521) can rotate only by a preset angle (e.g., 5 to 20º) so that the movement trajectory of the pillar support wing (7523) is corresponding to the rotational angle of the rotational pillar (7521).

The first wing support spring (7532) is installed in one side of the support wing mounting groove (7531) after the pillar support wing (7523) is mounted and supports one side of the pillar support wing (7523).

The second wing support spring (7533) is installed in the other side space of the support wing mounting groove (7531) after the pillar support wing (7523) is mounted to support the other side of the pillar support wing (7523).

The frame support member (700) having the configuration as described above effectively buffers vibrations or shocks generated between the first support plate member (710) and the second support plate member (720) as the cover support member (750) is inserted into the inside of the rotational cover member (740) while rotating as the gap between the first support plate member (710) and the second support plate member (720) decreases, or as the cover support member (750) is exposed while rotating from the inside of the rotational cover member (740) while the gap between the first support plate member (710) and the second support plate member (720) increases.

The above-described embodiments are for illustrative purposes, and those skilled in the art will appreciate that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. Therefore, the above-described embodiments should be understood as illustrative and not restrictive in all respects. For example, each component described as a single entity may be implemented in a distributed manner, and likewise, components described as distributed may be implemented in a combined manner.

The scope of protection sought by this specification is indicated by the claims described below rather than the detailed description above, and should be interpreted to include all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts.

10: Microfiber cleaning mop
11: 1st absorption layer
12: Cleaning surface
13: Second absorption layer
14: Ground floor
15: Loop Velcro
16: Polytape
20: Border pressure frame
100: "ㅁ" shaped frame body
200: 1st frame anchoring home
300: "ㅁ" shaped pressurized frame
400: 2nd frame mounting home
500: Pressurized Buffer

Claims (11)

A first absorbent layer manufacturing step for manufacturing a first absorbent layer made of an eco-friendly nonwoven fabric using recycled materials;
A cleaning surface forming step for forming a cleaning surface composed of recycled ultra-fine fibers and scrub material at regular intervals along the upper surface of the first absorbent layer manufactured by the first absorbent layer manufacturing step;
A second absorbent layer manufacturing step for manufacturing a second absorbent layer of ultrafine fiber fabric using recycled yarn;
A bottom layer manufacturing step for manufacturing a bottom layer on which a loop-shaped Velcro is formed using recycled monofilament on the bottom;
A lamination step of sequentially laminating the bottom layer, the second absorbent layer, and the first absorbent layer from the lower side; and
A tape finishing step for manufacturing a cleaning ultrafine fiber mop by finishing along the edge of a laminate comprising the bottom layer, the second absorbent layer, and the first absorbent layer using a polytape made of recycled materials;
The above second absorption layer is,
It is made of 0.5 denier microfiber fabric.
Further comprising a label adding step for adding a label with a description of the product to one side of the lower surface of the floor layer prior to the tape finishing step;
Further comprising a tag addition step of adding a color tag made with a color to distinguish the intended use of the product to one side of the lower surface of the floor layer prior to the tape finishing step;
It further includes a step of pressing the edge of the ultra-fine cleaning mop by alternately stacking the edge pressing frame and the ultra-fine cleaning mop, and then pressing down the edge pressing frame located at the top using a hydraulic cylinder to pressurize each edge of the ultra-fine cleaning mop.
The above border pressure frame is,
A “ㅁ” shaped frame body formed in a “ㅁ” shape corresponding to the shape of the edge of the above-mentioned ultra-fine cleaning mop;
A first frame fixing groove formed along the bottom surface of the above “ㅁ” shaped frame body;
A “ㅁ” shaped pressurizing frame formed in a “ㅁ” shape corresponding to the shape of the bottom surface of the “ㅁ” shaped frame body and seated in the first frame seating groove so that the lower portion is exposed from the first frame seating groove;
A second frame mounting groove formed along the upper surface of the "ㅁ"-shaped pressurizing frame so that the lower part of another "ㅁ"-shaped pressurizing frame installed on another "ㅁ"-shaped frame body arranged on the upper side of the "ㅁ"-shaped frame body can be mounted; and
A method for manufacturing an ultra-fine cleaning mop using recycled fibers, comprising: four pressurizing buffer members installed at each of the four corners of the first frame mounting groove and supporting the upper side of each corner of the “ㅁ” shaped pressurizing frame mounted in the first frame mounting groove.
delete delete delete delete delete In the first paragraph,
The above pressurized buffer portion,
A settling projection formed by protruding upward from the upper side of the corner of the above “ㅁ” shaped pressurizing frame;
An upper mounting groove formed on the upper surface of a corner of the first frame mounting groove facing the mounting jaw;
A lower mounting groove formed on the upper side of the mounting protrusion opposite the upper mounting groove; and
A method for manufacturing an ultra-fine cleaning mop using recycled fibers, comprising: a frame support member having an upper portion secured in the upper securing groove and a lower portion secured in the lower securing groove to support the securing jaw;
In Article 7,
The above frame support member,
A first support plate portion that is secured to the upper mounting groove and supports the upper side of the corner of the first frame mounting groove;
A second support plate part spaced apart from the first support plate part, facing the first support plate part, and seated in the upper seating groove to support the seating step;
A rotary connecting bearing part installed on the lower side of the first support plate part;
A rotary cover part that is rotatably connected and installed on the lower side of the first support plate part by the rotary connection bearing part; and
A method for manufacturing an ultra-fine cleaning mop using recycled fibers, comprising: a cover support part installed on the upper end of the second support play part and interlocked and connected to the inner side of the rotating cover part to support the rotating cover part;
In Article 8,
The above rotating cover part,
A cover body formed in a cylindrical shape;
A fastening head that protrudes from the upper end of the cover body to correspond to the shape of the fastening groove of the rotating connecting bearing part so that it can be fastened to the rotating connecting bearing part;
A support mounting groove formed to extend in the vertical direction along the inner side of the cover body while forming an opening in the lower side of the cover body so that the cover support portion can be inserted and forming an inner diameter corresponding to the outer diameter of the cover support portion;
A spiral line, which is an imaginary line formed in a spiral direction along the inner surface of the support mounting groove; and
A method for manufacturing an ultra-fine cleaning mop using recycled fibers, comprising: a plurality of gear blocks, each of which is installed in a row at regular intervals along the above spiral line and forms a gear mountain along a front end exposed to the support mounting groove;
In Article 9,
The above cover support part,
A transmission member formed in a cylindrical shape with an outer diameter corresponding to the inner diameter of the support portion mounting groove, fixedly installed on the upper end of the second support portion, and installed on the inner side of the support portion mounting groove to mesh with the gear teeth of the gear block and support the cover body;
A rotating member that is installed upright and rotatably connected to the upper center of the second support play portion and is inserted into the inside of the transmission member and connected, and is rotated by an external force transmitted from the rotation cover portion via the transmission member; and
A plurality of return members are installed at regular intervals along the lower side of the rotating member from the upper side of the second support play portion to prevent rotation of the rotating member and at the same time return the rotating member rotated by an external force to the original position;
The above absence of transmission,
A transmission body formed in a cylindrical shape having an outer diameter corresponding to the inner diameter of the support portion mounting groove and fixedly installed on the upper end of the second support portion;
A pillar mounting groove formed to extend in the vertical direction along the inner side of the transmission body while forming an opening in the lower side of the transmission body so that the rotation member can be inserted and positioned, and forming an inner diameter corresponding to the outer diameter of the rotation member;
A gear moving groove formed in a spiral shape along the outer surface of the transmission body corresponding to the shape of the spiral line so that the plurality of gear blocks can move as the external force is transmitted to the cover body while all of the plurality of gear blocks are settled; and
A method for manufacturing an ultra-fine cleaning mop using recycled fibers, comprising: a plurality of transmission gears, spaced apart at regular intervals along the inner side of the transmission body while facing the gear movement groove and connected so as to be able to rotate repeatedly, each end of which is exposed to the gear movement groove and connected so as to mesh with the gear teeth of the gear block by gear engagement, and each other end of which is exposed to the pillar mounting groove and connected so as to mesh with the rotating member by gear engagement;
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