MXPA06007665A - Cleaning tool and method of manufacturing cleaning part thereof - Google Patents

Abstract

A cleaning tool and a method of manufacturing the cleaning part of the cleaning tool. The cleaning tool capable of sufficiently developing cleaning capacity even for cleaning in a small space comprises the cleaning part (1) and a grip part (2). The method of manufacturing the cleaning part (1) comprises the steps of forming a bulky section forming part (3) by bending a sheet stacked body having an adhered part formed by adhering a sheet-like fiber bundle (7) to a sheet along the adhered part, bending the sheet stacked body having the bulky section forming part (3) formed thereon to face the bulky section forming part (3), and forming the contact surfaces of the opposed sheet-like fiber bundles (7) integrally with each other so that these contact surfaces are adhered to each other. Opened grip insert ports (4) are formed at one end of the bulky section forming part (3), and the support bars (5) of the grip part (2) are inserted into grip insert parts (6) formed in the bulky section forming part (3).

Description

CLEANING TOOL AND MANUFACTURING METHOD OF THE CLEANING PART OF THE SAME FIELD OF THE INVENTION The present invention relates to a cleaning tool comprising a cleaning component and a handle component, and a method for manufacturing a cleaning compound for said cleaning tool.

BACKGROUND OF THE INVENTION [0002] Shakers have been used in the past for cleaning tools to remove dust that accumulates on trunks and other means of this type; computers, lighting devices, and other such electrical products; and interior walls, thresholds and sills, and so on. A shaker is constructed such that a plurality of rope-shaped bands are coupled to the distal end and a handle component, and the surface of a powdery object is struck with the rope-shaped bands to remove dust. Therefore, a conventional shaker has no rub function, so it is unable to remove dust without dispersing it into the air. The proposals that have been made with the purpose REF.:173876 to help solve this inconvenience for the shakers, include a cleaning tool in which a stirred cleaning cloth with a rubbing component and a shaking component is coupled to the head at the distal end of a handle component (Japanese Patent Application Laid Open to the Public H10-43115), and a manual wiper comprising a handle component, a head component and a cleaning cloth, with the main portion formed at the center of the head component, and a thin flexible portion formed around the main portion (Japanese Patent Application Laid-Open 2000-83883). However, with the cleaning tool described in Japanese Patent Application Laid-Open No. H10-43115, the rubbing component did not offer sufficient rubbing capacity, and the tool was inconvenient to use. With the manual wiper described in Japanese Patent Application Laid-open to the Public 2000-83883, not only the rub operation was lacking, but the narrow spaces could not be properly cleaned. The present invention was conceived in order to solve the above problems, and an object thereof to provide a cleaning tool showing suitable cleaning performance even in the cleaning of narrow slits.

BRIEF DESCRIPTION OF THE INVENTION The present invention provides a cleaning tool comprising a cleaning compound and a handle component, wherein the cleaning component is designed such that a group of fibers in the form of a sheet and a sheet are joined to producing a sheet laminate having a joining portion, this sheet laminate is flexed along the joining portion, to form a bulky component forming portion, the sheet laminate into which the portion of the sheet has been formed. formation of the bulky component is flexed such that the forming portions of the bulky component are crossed with one another, and integrated such that the contact portions of the opposing leaf-like fiber groups are joined together, and the The handle component support rods are inserted into a handle insert component having handle insert openings made at one end of the handle component. the forming portions of the bulky component and formed within the forming portion of the bulky component. The cleaning tool of the present invention is constituted such that the sheet laminate is flexed, and the contact surfaces of the opposing fiber groups in sheet form, are partially joined together to form a forming portion in the bulky component , and the sheet laminate in which the forming portion of the bulky component has not been formed, is flexed and the contact surfaces of the opposing fiber groups in the form of a sheet, are joined together, forming in a bulky form, and the insert openings of the handle of the bulky portion made at one end, and the insertion component of mango in the forming portion of the bulky component. Consequently, this cleaning tool can be made into a thinner form, which means that the dust and dirt in the narrow oblique slits can be efficiently cleaned by rubbing. Also, since a group of sheet-like fibers produced by clumping the fibers, is used for the cleaning component in this cleaning tool, even if the powder is hidden in tight cracks in a tight space, the fibers that They constitute the group of leaf-shaped fibers can reach these narrow cracks and efficiently clean any dust that is hiding in these cracks, providing excellent shaking performance. Also, with this cleaning tool, the handle insert component is formed by bending sheet lamination, so that there is no need to separately produce and install any parts that could serve as the handle insert component, which It means that fewer parts make up the cleaning tool. The present invention provides a cleaning tool comprising a cleaning component and a handle component, wherein the cleaning component is designed such that a group of fibers in the form of sheets and a sheet having a fiber component are partially joined to produce a sheet laminate having a joining portion, this sheet laminate is flexed along the joining portion to form a portion of the bulky component, the sheet laminate into which the portion of the bulky component has been formed. it is flexed so that the forming portions of the bulky component are crossed with each other, the group of fibers in the form of a sheet on the inside, and integrated such that the contact surfaces of the groups of fibers in the form of a sheet are joined together, and the support rods of the handle component are inserted into an insert component having insert openings of Related mangoes at one end of the bulking component forming portions and formed within the bulking component forming portion. With this cleaning treatment, in addition to the aforementioned effects of being formed into a thinner form and is able to efficiently remove dust and dirt from narrow slits, and to reduce the number of parts required, the dust particles more Large that can not be swept by rubbing are with the fibers constituting the group of fibers in sheet form can be swept by rubbing with the fiber component provided to the sheet, resulting in even better cleaning performance. With the cleaning tool of the present invention, the group of sheet-shaped fibers can be formed by layer rubbing a plurality of groups of sheet-like fibers. With this cleaning tool, because a plurality of the layers of sheet-like fiber groups are used as the group of sheet-like fibers, more fibers are involved in cleaning and in the release of dust by rubbing, more efficiently. With the cleaning tool of the present invention, the group of fibers in the form of a sheet may comprise a first group of fibers in the form of a sheet composed of numerous fibers and a second group of fibers in the form of a sheet composed of fibers thicker than the fibers. fibers that constitute the first group of fibers in the form of a leaf. With this cleaning tool, the group of fibers in the form of a sheet comprises a first group of fibers in the form of a sheet and a second group of fibers in the form of a sheet composed of fibers thicker than the fibers that constitute the first group of fibers in the form of fibers. leaf shape, and the stiffness of the first group of leaf-shaped fibers may be different from that of the second group of leaf-shaped fibers. Specifically, if the fibers constituting a group of sheet-like fibers are thicker, the stiffness will be higher, so that the second group of sheet-like fibers can be made more rigid. Also, the thinner the fibers that constitute the group of fibers in the form of a leaf, the thinner the fiber group will be when the fibers are made into a group of leaf-shaped fibers. Due to this, with this cleaning tool, the shaker can be efficiently removed by rubbing with the second group of fibers in the form of a stiffer sheet, while this dust that has been removed by rubbing can be efficiently collected by the first group of fibers in the form of a thinner sheet, which means that more efficient cleaning is possible. With the cleaning tool of the present invention, the group of fibers in the form of a sheet can be constituted such that a first group of fibers in the form of a sheet composed of numerous fibers and a second group of fibers in the form of a sheet composed of fibers that they are thicker and shorter than the fibers that make up the first group of leaf-shaped fibers, are partially joined. When the fibers constituting a group of leaf-shaped fibers are shorter, these fibers become more rigid, which means that the second group of leaf-shaped fibers can be made even more rigid. Therefore, with this cleaning tool, since the fibers that make up the second group of fibers are thicker and shorter than the fibers that constitute the first group of fibers in the form of a sheet, they are more rigid, and these fibers Stiffer, more powerfully rubbed the dust from the narrow slits, and the dust that is thus removed by rubbing is picked up by the finer fibers, which provides even more effective cleaning and also helps prevent thick fibers from come to entangle with fine fibers. With the cleaning tool of the present invention, the cleaning component can be produced by interposing a fiber group body composed of a first group of fibers in the form of a sheet and / or a second group of fibers in the form of a sheet. between the groups of sheet-shaped fibers that face one another when a sheet laminate is flexed, and the body of the fiber group and the sheet-like fiber group are united, where they are in contact with the fiber group. other.

This cleaning tool can be constituted such that the distal ends of the fibers constituting the first group body of fibers are above the upper end of the bulky component. Therefore, with this cleaning tool, any powder or the like that is above the bulky component can be efficiently removed by rubbing with the body of the fiber group. With the cleaning tool of the present invention, the sheet laminate can be produced by sandwiching the group of sheet-like fibers with the sheet and attaching the sheet body to the group of sheet-shaped fibers to thereby cover the surface of the sheet. opposite side at the site of the joint portion. With this cleaning tool, since the group of leaf-shaped fibers is sandwiched by the leaf and the body of the leaf, the complete configuration of the leaf-shaped fiber group is stabilized, giving the cleaning tool better integrity complete With this cleaning tool of the present invention, the group of sheet-shaped fibers may comprise a plurality of first groups of sheet-shaped fibers and / or a plurality of second groups of sheet-shaped fibers. With this cleaning tool, the use of a plurality of groups of fibers in the form of a sheet allows the powder to be removed by rubbing more efficiently by a greater number of fibers. With this cleaning tool of the present invention, the group of sheet-shaped fibers can be produced by alternately laminating the first groups of sheet-shaped fibers and the second groups of sheet-shaped fibers. With this cleaning tool, the groups of leaf-shaped fibers are such that the powder is sufficiently removed by rubbing by the stiffer, thicker fibers, which make up the second group of sheet-shaped fibers, while the powder that has The friction removed is picked up by the finer fibers that make up the first group of sheet fibers, so that the cleaning component is able to clean more efficiently. Also, these groups of leaf-shaped fibers effectively contribute to preventing entanglement of coarse fibers with fine fibers. With this cleaning tool of the present invention, the sheet can be composed of a non-woven fabric. With this cleaning tool, if the sheet has a component of strips, the fine powder can be efficiently collected by the fibers of the non-woven fabric, which constitutes the strip component. Also, with this cleaning tool the group of fibers in the form of a sheet is placed towards the internal part where the strip component of the sheet is placed, the fine powder is removed by rubbing the fibers that constitute the group of fibers in the sheet. sheet form, and this powder which has been removed by rubbing, can be efficiently reproduced by the fibers of the non-woven fabric constituting the strip component. The present invention also provides a method for manufacturing a cleaning component for a cleaning tool, wherein a group of sheet-like fibers produced by the clustering of the fibers in the form of a sheet is laminated by a sheet having a component of strips, these are partially joined to form a sheet laminate, and the sheet laminate is then flexed along its joining portion, so that the group of sheet-like fibers is flexed then folded into the joining portion, whereby a bulking component formation portion is produced, after which the sheet having the strip component is bent back towards the group of sheet-like fibers on the opposite side, to encircle thus the forming portion of the bulky component and furthermore the forming portion of the bulky component is selected so that the side of the sheet-like fiber group is on the side of the sheet. to internal part, and the group of leaf-shaped fibers and the sheet having the strip component are joined at intervals so that the contact surfaces of the sheet-like fiber groups are attached to each other. The method for manufacturing a cleaning component of the present invention makes it easy to provide a cleaning tool that provides sufficient cleaning performance even in the cleaning of narrow slits. In addition, the present invention provides a method for manufacturing a cleaning component for a cleaning tool, comprising the steps of notching to form a strip with a long blade used to form a sheet having a strip component.; the formation of a joining portion, by joining, in the direction of the width of the sheet, a long laminated sheet obtained by rolling a long sheet which has been coined to form a strip, firstly with a group of fibers in the form of long sheet produced by grouping the fibers into the shape of a sheet, and then with a sheet of substrate to support the sheet-like group of fibers. Obtaining a laminated sheet to form a cleaning component, by dividing the longleaf laminate between the joining portions; the formation of a bulky component forming portion by trimming one of the side portions flanking the attaching portion of the sheet having a strip component with the laminated sheet for forming a cleaning component, cutting both portions laterals flanking the binding portions of the substrate sheet, and then flexing along the joining portions so that the group of sheet-like fibers is doubled bent, and joining so that the joint portions are shaped tubular; and forming handle insertion openings in one end of the bulky component forming portion by bending the laminated sheet, to form a cleaning component in which the bulky component forming portion has been formed, so that groups of sheet-like fibers are on the inner part, and integrating so that the contact surfaces of the sheet-like fiber groups are joined to one another. The method for manufacturing a cleaning component of the present invention makes it easy to provide a cleaning tool that provides sufficient cleaning performance and even in the cleaning of narrow slits, and when the cleaning tool is equipped with a sheet having a cleaning component. fibers, the insert component of the handle can be maintained in a bulky shape and the periphery of the handle insert component can be surrounded by the sheet-like fiber group allowing a firmer handle insert component to be formed.

BRIEF DESCRIPTION OF THE FIGURES Figure 1 is an exploded oblique view of an example of the cleaning tool of the present invention; Figure 2 is an oblique view of a sheet laminate in the manufacturing process of the cleaning tool of the present invention; Figure 3 is a cross-section along the line I-I in Figure 2; Figure 4 is an oblique view of a sheet laminate in the manufacturing process of the cleaning tool of the present invention. Figure 5 is an oblique view of a sheet laminate in the process of manufacturing the cleaning tool. of the present invention; Figure 6 is an oblique view of yet another example of the cleaning tool of the present invention; Figure 7 is an exploded oblique view of an example of the cleaning tool of the present invention; Figure 8 is a vertical cross-sectional view along the line II-II in Figure 7; Figure 9 is an oblique view of a step of the method for manufacturing a cleaning component of the cleaning tool of the present invention; Fig. 10 is an oblique view of yet another step of the method for manufacturing a cleaning component of the cleaning tool of the present invention; Fig. 11 is an oblique view of yet another step of the method for manufacturing a cleaning component of the cleaning tool of the present invention; Fig. 12 is an oblique view of yet another step of the method for manufacturing a cleaning component of the cleaning tool of the present invention; Figure 13 is an oblique view of yet another step of the method for manufacturing a cleaning component of the cleaning tool of the present invention; Fig. 14 is a schematic process of another method for manufacturing a cleaning component of the cleaning tool of the present invention, - Fig. 15A is a view along the arrow A in figure 14; Figure 15B is a view along the arrow B in Figure 14; Figure 15C is a view along the arrow C in Figure 14; Figure 16 is a vertical cross-section along the line X-X in Figure 15B; Figure 17 is a vertical cross-section along the line XI-XI in Figure 15C; Figure 18 is a vertical cross-section illustrating the state when one side of the non-woven fabric flanking the joining portion, and both sides of the sheet of the substrate flanking the joining portion are cut along the perforated lines from the laminated sheet, to form the cleaning component shown in Figure 17; Figure 19 is an oblique view of the state when the sheet laminated to form the cleaning component shown in Figure 18 is flexed along the joint portion; Figure 20 is a vertical cross section illustrating the state when the joint has been made to form a bulky tubular control insert component and the attachment portion of the laminated sheet to form a flexed cleaning component as shown in the figure 19; Figure 21 is an oblique view of the state when the laminated sheet is bent to form a cleaning component in which a handle insert component has been formed as shown in Figure 20; Figure 22A is a front view of one embodiment of a handle component of the cleaning tool of the present invention; Fig. 22B is a plan view of one embodiment of a handle component of the cleaning tool of the present invention; Figure 23 is a front view of the handle component when folded; Figure 2A is a vertical cross-section of the flexure mechanism of the handle component; Figure 24B is a vertical cross-section along the line D-D in Figure 22A; Figure 25A is a plan view of one embodiment illustrating another example of the handle component; Fig. 25B is a plan view of the state when the clamping component of the handle component in Fig. 25A is extended; Figure 26A is a vertical cross-section along the line E-E in Figure 25A; Figure 26B is a vertical cross-section illustrating the state when the protrusion in Figure 26A is pushed in; Figure 27A is a side view of the main component of the joint portion, between a support rod and the clamping component of the handle component in Figure 25A; Fig. 27B is a side view of the main component of the state when a stop of the fastening component in Fig. 27A has been moved; Figure 28A is a vertical cross section of the main component of the proximity of the stop in Figure 27A; Figure 28B is a vertical cross section of the main component of the proximity of the stop in Figure 27B; Fig. 29A is a vertical cross section of the main component of the vicinity of the joint portion in Fig. 27A; and Figure 29B is a vertical cross section of the main component of the vicinity of the joint portion in Figure 27B.

DETAILED DESCRIPTION OF THE INVENTION The cleaning tool of the present invention comprises a cleaning component and a handle component, wherein the cleaning component is designed such that a group of sheet-like fibers and a sheet are joined to produce a sheet laminate in which a joining portion is formed, this sheet laminate flexed along the joining portion, to form a bulky component forming portion, the sheet laminate in which the component forming portion bulky has been formed, is bent so that the forming portions of the bulky and formed component are crossed with one another, and integrated such that the contact surfaces of the opposed sheet-like fiber groups are joined together, and the handle component support rods are inserted into a handle insert component formed within the forming portion of the component bulky and having handle insert openings made at one end of the bulky component forming portions. Examples of the sheet used in the cleaning component include paper, synthetic resin sheets, and nonwoven fabric, but nonwoven fabric is preferred. This nonwoven fabric may be nonwoven fabric, spun lace, nonwoven fabric of fused filaments, thermal bond nonwoven fabric, non-woven air fabric, nonwoven fabric joined by dots, and the like, but the fabric does not Knitted woven by spinning and thermally nonwoven fabric are preferred. Examples of the fibers that make up the non-woven fabric include natural fibers, synthetic fibers, and composite fibers, but synthetic fibers and composite fibers are preferred because of their thermal fusibility. The nonwoven fabric preferably has a basis weight of about 20 to 100 g / m2. Even if the sheet is composed of a material that is not thermally fusible, the sheet and the sheet-like fiber group can be joined by thermal fusion by rolling a thermally fusible material such as a hot melt adhesive. The leaf is not limited to a single leaf, and may consist of two or more leaves. The group of fibers in the form of a sheet is produced by grouping the fibers in the form of a sheet, and this may comprise numerous fibers sufficiently unified so that the individual fibers will not separate although the fibers may be partially bound together by merger or similar, if necessary. The group of leaf-shaped fibers can be obtained, for example, by a method in which numerous long fibers are grouped in the form of sheets, these products are attached perpendicularly to the longitudinal direction at suitable intervals, and this product is then cut in the middle part of the adjacent joining portions. Examples of the fibers constituting the fiber group in the form of sheets include cotton, wool and other natural fibers, polyethylene, polypropylene, polyethylene terephthalate, nylon, polyacrylic and other synthetic fibers, such, and core / sheath fibers, fibers from island to sea, fibers side by side, and other composite fibers of this type, but synthetic fibers and composite fibers are preferred because of their thermal fusion capacity, and the core / sheath fibers in which the core is polypropylene and the sheath is made of polyethylene, they are particularly favorable because they combine the excellent thermal fusion capacity of the polyethylene that make up the sheath with the good rigidity of the polypropylene that makes up the core. The fibers that constitute the group of fibers in sheet form have a thickness of approximately 0.01 to 0.3 mm. A group of fibers in the form of a sheet 7 can consist solely of fibers of the same thickness, or made up of fibers of two or more different thicknesses, and can be made up only of fibers of the same type, or made up of fibers of two or more different types. The group of fibers in the form of a sheet can be made up of fibers of different colors, regardless of whether the thickness and type of the constituent fibers is the same or different. It is also possible to laminate two or more groups of fibers in sheet form. When two or more groups of sheet-like fibers are laminated, the groups of sheet-shaped fibers of different thickness and of different colors and types of fiber can be combined, as desired. By using groups of fibers in the form of sheets of different colors together, the design capability of the cleaning tool of the present invention is improved. When a plurality of groups of sheet-like fibers having different fiber thicknesses, fiber types, colors, etc., are used together, there are no particular restrictions on the number of laminations, but the number is usually from two to ten. . When a plurality of groups of sheet-like fibers are laminated for use in a cleaning tool, the groups of fibers in the form of cleaning tool sheet of the present invention may be constituted such that a first group of fibers in the form of sheet composed of numerous fibers and a second group of fibers in the form of sheet composed of fibers that are thicker and shorter than the fibers that constitute the first group of fibers in sheet form, are partially joined. This cleaning tool will now be described in detail through the reference to the figures. Fig. 1 is an oblique exploded view of an example cleaning tool of the present invention, comprising a cleaning component 1 and a handle component 2. The handle component 2 has a holding component 14 and support rods 5. The cleaning component 1 and the handle component 2 are integrated by inserting the support rods 5 of the handle component 2 into the handle insert components 6, formed at the site of a component forming portion. bulky 3, through handle insertion openings 4 made in one end of the bulking component portion 3 of the cleaning component 1. In Figure 1, 45 is an anti-slip bulge to prevent the support rods 5 from release the insert components 6 of the handle. The cleaning component 1 is constituted by the group of fibers in the form of a sheet and a sheet 9. As shown in FIG. 5, the group of fibers in sheet form 7 of the cleaning component 1 comprises a first group of fibers in sheet form 7a produced by harvesting the fibers in the form of a sheet, and a second group of sheet shaped fibers 7b produced by harvesting in the form of sheet fibers which are thicker (have a larger size) ) than the fibers that make up the first group of sheet-shaped fibers 7a. As a result, the powder is refined by rubbing by the stiffer, thicker fibers, and the dust that has been removed by rubbing is picked up by the finer fibers, which provides more effective cleaning. The thickness of the fibers constituting the first group of fibers in the form of a sheet is preferably of a diameter of 10 to 50 μm. The thickness of the fibers constituting the second group of sheet-like fibers is greater than the thickness of the fibers constituting the first group of sheet-like fibers, but it is preferable that the diameter is 60 to 300 μm, to which then the second group of sheet-shaped fibers 7b will suitably be more rigid than the first group of sheet-shaped fibers 7a. With this cleaning tool, the first group of sheet-like fibers 7a, and the second group of sheet-like fibers 7b are constituted such that the fibers constituting the second group of sheet-shaped fibers 7b are shorter than the fibers containing the first group of fibers in sheet form 7a. The length of the fibers constituting the second group of sheet-shaped fibers 7b is less than the length of the fibers constituting the first group of sheet-shaped fibers 7a, and it is preferable that these be about 1 to 10 mm shorter than the fibers that make up the first group of sheet-like fibers 7a. When the sheet-like fiber group 7 comprises the first groups of sheet-shaped fibers alternately laminated with the second groups of sheet-like fibers, the group of sheet-like fibers 7 operates such that the powder is efficiently removed. by rubbing by the stiffer, thicker fibers constituting the second group of leaf-shaped fibers 7b, while the dust that has been removed by rubbing is picked up by the finer fibers containing the first group of fibers in the form of sheet 7a, so that the cleaning component 1 is able to clean more effectively. Also, a group of sheet-like fibers 7 such as this is preferable because this helps to prevent coarse fibers from becoming entangled with the fine fibers. Examples of the fibers constituting the first group of sheet fibers 7a include the same as those listed above for the group of sheet fibers, namely cotton, wool and other natural fibers, polyethylene, polypropylene, terephthalate polyethylene, nylon, polyacrylic, and other synthetic fibers, and core / sheath fibers, island-in-the-sea fibers, side-by-side fibers, and other composite fibers, but synthetic fibers and composite fibers are preferred because of their thermal fusion capacity, and the core / sheath fibers in which the core is polypropylene and the sheath is made of polyethylene, are particularly favorable because they combine the excellent thermal fusion capacity of the polyethylene that makes up the sheath, with the good rigidity of the polypropylene that constitutes the core. The fibers constituting the second group of sheet-shaped fibers 7b can be polypropylene, polyethylene terephthalate, PBT, or other such thermoplastic fibers, for example. The first group of sheet-shaped fibers 7a and the second group of sheet-shaped fibers 7b can be made up of only the same type of fibers or made up of fibers of two or more different types, and can be made of different fiber colors , regardless of whether the constituent fibers are the same or of different types of thicknesses. Also, two or more of the first groups of sheet-shaped fibers 7a can be laminated with two or more of the second groups of sheet-shaped fibers 7b. When the cleaning component 1, a binding portion 10 is formed in the region where the group of sheet-like fibers 7 and sheet 9 overlap in the sheet laminate formed by the lamination of sheet-like fiber groups 7 and the sheet 9. This sheet laminate flexed with the sheet 9 towards the internal part (figure 4), the portion 3 forming the bulky component with the groups of fibers in the form of sheet 7 that being each other at the same time. length of the joining portion 10. The sheet laminate in which the forming portion 3 of the bulky component has been formed is then flexed such that one end of the longitudinal portion moves towards the other end, and the contact surfaces of the groups of sheet-shaped fibers 7 facing each other with the results of this flexure, are joined in the vicinity of the formation portion 3 of the bulky component, forming a connecting portion 11 and integrating the whole (figure 5) . The cleaning component 1 of this cleaning tool can be manufactured as follows. As shown in Figures 2 and 3, the group of sheet-like fibers 7 and sheet 9 are laminated and joined at the site of a portion 12, where the two overlap (for clarity purposes, the area of the portion 12 where the group of fibers in the form of sheet 7 and sheet 9 are joined, is shaded). Examples of bonding methods include thermal fusion, bonding with adhesive, and sewing, but the group of sheet fibers and sheet 9 are preferably made of thermally fusible materials, because it can also be achieved by thermal fusion since this allows the joining and integration to be carried out easily by heating and pressing with a hot roller, or the like. (The following description assumes that the group of fibers in the form of sheet 7 and sheet 9 that are to be made from thermally fusible materials). The portion 12 where the group of sheet-like fibers 7 and the sheet 9 are joined, is formed where the intermediate part of the sheet-like fiber group 7 is walled perpendicularly to the fiber direction of the fiber group in the form of sheet 7. As shown in Figure 3, the group of sheet-shaped fibers and sheet 9 are placed together and placed in portion 12 to form a sheet laminate 13a in which the joining portion 10 is formed. The sheet laminate 13a in which the joining portion 10 is formed, is flexed with the sheet 9 towards the inner part, forming the portion 3 for forming the bulky component in the direction in which the connecting portion 10 was formed (figure 4). Next, one end of the longitudinal direction of the resultant sheet laminate 13b is bent towards the other end to form the sheet laminate 13c, and the sheet-like fiber groups 7 that are facing each other, as a result of this bending, they are joined where they come into contact with each other, whereby a joint portion 11 is formed and the cleaning component 1 is obtained. In this case, it is preferable that the fiber groups in the form of sheet 7 that are facing each other are joined together in the vicinity of the portion 3 formation of the bulky component (Figure 5). If the thermal fusion is used for this purpose, not only, the groups of fibers in the form of opposing sheets 7 can be joined, but also the group of fibers in the form of sheet 7 and sheet 9 can be joined at the same time. Also, the cleaning component 1 of the cleaning tool of the present invention can be constituted such that when the sheet laminate 13c is formed by flexing one end in the longitudinal direction of the sheet laminate 13b toward the other end, a fiber group body 70 produced by laminating the first group of sheet-like fibers 7a and the second group of sheet-like fibers 7b is interposed between groups of sheet-like fibers 7 that are facing each other as a result of this bending, so that the distal end in at least one direction of the fiber of the body 70 of the fiber group is placed above the portion 3 for forming the bulky component (Figure 6). In this case, since the cleaning component 1 is constituted such that the distal ends of the fiber direction of the first group of fibers in the form of a leaf and the second group of fibers in the form of a leaf face both above and above. under the portion 3 of formation of the bulky component, the cleaning tool is able to trap the dust and the earth with the group of fibers in sheet form 7, and at the same time, traps the dust and the earth above the portion 3 for forming the bulky component with the body 70 of the fiber group. There are no limitations on the number of laminations of the first group of fibers in the form of sheet 7a, and of the second group of fibers in the form of sheet 7b in the body 70 of the fiber group. If the body 70 of the fiber group is produced by laminating numerous first groups of sheet-like fibers 7a and second groups of sheet-like fibers 7b, the cleaning tool will be able to form a state in which many of the the constituent fibers of the first group of sheet-like fibers 7a and of the second group of sheet-like fibers 7b are higher than the portion 3 of forming the bulky component allowing the dust and dirt that are higher than the portion 3 bulky component formation are trapped more efficiently. As well, it is preferable that the body 70 of the fiber group be constituted by alternating lamination of the first groups of sheet-shaped fibers 7a with the second groups of sheet-shaped fibers 7b, because, as discussed above, the The sheet-like fiber group 7 will function such that the powder is efficiently removed by rubbing by the stiffer, thicker fibers, which make up the second group of sheet-shaped fibers 7b, while the powder that has been removed by rubbing it is picked up by the finer fibers that constitute the first group of fibers in sheet form 7a, so that the cleaning component 1 is able to clean more effectively. The cleaning component 1 of the cleaning tool of the present invention can also be constituted such that a quarter of the sheet is laminated on the outside of the group of fibers in the form of sheet 7. In this case, the cleaning component 1 it can be manufactured by laying the sheet body so that the sheet-like fiber group 7 is sandwiched by the body of the sheet and the sheet 9, forming the sheet laminate 13a, and flexing the sheet laminate 13a of the same way that was discussed previously. The sheet body is preferably a nonwoven fabric. In this case, the sheet body, the sheet-like fiber group 7, and the sheet 9 can be easily joined and integrated by thermal fusion, whereby the sheet laminate 13a is formed. The cleaning component 1 can be such that the group of fibers in the form of sheet 7 is sandwiched by the sheet body and the sheet 9, which stabilizes the complete configuration of the group of fibers in the form of sheet 7 and holds the tool together. Overall cleanliness better. The cleaning component of the cleaning tool of the present invention can make use of a sheet that is equipped with a strip component on one side. The cleaning tool of the present invention in the above case will now be described in detail by reference to the drawings. The cleaning tool is constituted as shown in Figure 7. Figure 7 is an oblique exploded view of yet another example of the cleaning tool of the present invention. The cleaning tool comprises the cleaning component 1 equipped with the sheet-like fiber group 7 and the sheet 9, and the handle component 2 having the holding component 14 and the support rods 5. The cleaning component 1 and the handle component 2 are constituted such that they can be integrated by insertion of the support rods 5 and the handle component 2 and the handle insert components 6 formed at the site of the bulky component forming portion 3 , through the handle insertion openings 4, made at one end of the bulking component portion 3 of the cleaning component 1. In Figure 7, 45 is an anti-slip protrusion to prevent the support rods 5 are released from the handle insert components 6. The cleaning component 1 of this cleaning tool is such that the group of sheet-like fibers 7 and the sheet 9 having the strip component 8 are partially joined in the joining portion 10, producing a sheet laminate in the as the joining portion 10 is the portion 3 for forming the bulky component, this sheet laminate is flexed so that the side of the sheet-like fiber group 7 is towards the inner part, and the connecting portion 11 is provided and integrated in the vicinity of the portion 3 of formation of the bulky component in the groups of fibers in the form of opposing sheets. With this cleaning tool, the group of sheet-shaped fibers 7 can be formed by layering a plurality of groups of sheet-shaped fibers. In this case, the group of fibers in sheet form 7 can be constituted as described above, comprising a first group of fibers in the form of sheet 7a composed of numerous fibers, and a second group of fibers in the form of sheet 7b composed of thicker fibers (fibers that are larger in size) than the fibers that constitute the first group of sheet-shaped fibers 7a. Also, as discussed above, the thickness of the fibers constituting the first group of sheet-shaped fibers is preferably 10 to 50 μm in diameter, and the thickness of the fibers constituting the second group of fibers in the form of The sheet is greater than the thickness of the fibers constituting the first group of sheet-like fibers, and preferably the diameter is 60 to 300 μ. The group of fibers in sheet form 7 can also be constituted by the alternating lamination of the first groups of fibers in the form of a sheet and the second groups of fibers in the form of a sheet. In this case, the group of fibers in sheet form 7 will function such that the powder is efficiently removed by rubbing by the thicker, stiffer fibers constituting the second group of sheet-shaped fibers 7b, while the powder which has The friction removed is picked up by the finer fibers constituting the first group of fibers in sheet form 7a, so that the cleaning component 1 is able to clean more effectively. This is also preferable because it will help to prevent coarse fibers from becoming entangled with fine fibers. With the cleaning component 1 of this cleaning tool, the strip component 8 of the sheet 9 is preferably approximately 20 to 100 mm in length, and approximately 0.5 to 5 mm in width. The sheet 9 having the strip component 8 is not limited to a single sheet, and two or more sheets can be laminated. When a plurality of the sheets 9 having the strip component 8 are laminated together, all the sheets do not have to be the same, and the sheets 9 of different materials, colors, and the like, can be used together. There are no particular restrictions on how many of the sheets 9 are laminated, but the number is usually two to five.

A method for manufacturing the cleaning component 1 of this cleaning tool will now be described. As shown in Figure 9, the sheet-like fiber group 7 is laminated with the sheet 9 having the fiber component 8 on one side, and these are joined at the portion 12 where the two overlap (for of clarity, the area of the portion 12 is shaded where the group of fibers in the form of sheet 7 and the sheet 9 having the component of strips 8 are joined). Examples of the joining method include thermal fusion, adhesive bonding, and sewing, but when the sheet-like fiber group 7 and the sheet 9 having the strip component 8 are preferably made of thermally fusible material because the union can be achieved by thermal fusion, since it allows the joining and the integration to be easily carried out by heating and pressing with a hot roller or the like. The portion 12 where the group of fibers in sheet form and the sheet 9 having the component of strips 8 are joined, corresponds to the portion where the intermediate part of the group of fibers in the form of sheet 7 is walled perpendicular to the direction of The fiber of the group of fibers in sheet form 7. Next, as shown in Figure 10, the sheet laminate 13a, attached to the portion 12, which is part of the overlapped component between the group of leaf-shaped fibers 7 and the sheet 9 having the strip component 8, is flexed in the vicinity of the intermediate part perpendicular to the direction of the fibers of the group of fibers in sheet form 7, so that the fibers 7 face one opposite of the other, and are joined in the portion 12 of the overlapping component, forming the sheet laminate 13b in which the joining portion 10 serves as the portion 3 for forming the bulky component. Next, as shown in Figure 11, the sheet 9 having a strip component 8 in the sheet laminate 13b in which the portion 3 for forming the bulky component has been formed is flexed in the direction of the portion 3 for forming the bulky component, and the portion 3 for forming the bulky component of the sheet 9 is joined to the contact portions. When thermal fusion is employed for this purpose, the internal sides of the portion 3 for forming the bulky component in the sheet-like fiber group 7 can also be joined at the same time. After the attachment of the sheet 9 to the contact portions of the bulky component forming portion 3, as shown in Figure 12, the sheet 9 is bent backward to wrap the bulky component forming portion 3 to form a bulky component. the sheet laminate 13c. This sheet laminate 13c is flexed so that the side of the sheet-like fiber group 7 is towards the inner part (figure 13), and the cleaning component 1 is obtained by integrally joining the sheet-shaped group of fibers. 7 and the sheet 9 having the component 8 of strips, so that the contact surfaces of the group of fibers in the form of sheet 7, flexed, are joined. It is preferable that the joint is made such that the contact surfaces of the group of fibers in sheet form 7 are joined very closely to the portion 3 for forming the bulky component. If the thermal fusion is used for this purpose, the group of fibers in the form of sheet 7 and sheet 9 having a component of strips 8 can be joined at the same time between the groups of fibers in the form of sheet 7. Another method of the cleaning component 1 of this cleaning tool will now be described. Figure 14 illustrates yet another step of producing cleaning component 1, and describes an example of forming a sheet having the strip component from a three layer laminated nonwoven fabric. In Figures 14, 47a, 47b and 47c are long rolls of non-woven fabric, 48 is a group of sheet-like fibers, and 49 is a long sheet of substrate to support the group of sheet-like fibers. There are no particular restrictions regarding the material of the substrate sheet 49as long as it is in the form of a sheet, but a non-woven fabric is preferred. The non-woven fabrics 47a, 47b, and 47c are thinned as they are laid in layers one on top of the other, and a cutter roll 50 makes a plurality of cut 52, to form a fiber component in the longitudinal direction, in the resulting laminate 51 of the non-woven fabrics 47a to 47c (Figure 15A). A plurality of blades are provided around the peripheral surface of the cutter roll 50, to make the cuts 52, and if empty spaces are provided to the sheets, then non-continuous cuts 52 can be formed in the nonwoven fabric laminate 51, as it is shown in figure 15A. The provision of non-continuous cut 52 maintains the shape of the sheet of the non-woven fabric laminate 51. The non-woven fabric laminate 51 is then laminated with the sheet-like fiber group 48 and the substrate sheet 49 to form a laminated sheet 53, but it is preferable that perforations 55 are formed in the laminate 51 of non-woven fabric , as shown in FIG. 15B, with a perforation roller 54 prior to the sheet lamination formation 53. It is also preferable to provide perforations 57 (FIG. 17) in the substrate sheet 49, with a perforation roller 56 prior to the sheet laminate formation 53. Next, the non-woven fabrics 47a to 47c, the sheet-like fiber groups 48, and the substrate sheet 49 that make up the sheet laminate 53 are joined in the transverse direction, and the joint portions 58 are intermittently provided in the longitudinal direction of the sheet laminate 53, as shown in Figure 15B. When non-continuous cuts 52 are formed in the non-woven fabric laminate 51, as shown in Figure 15A, the joining portions 58 are preferably provided to the uncut portions 60. The attachment portions 58 are preferably formed by a method of heat sealing involving heating and pressing with a sealing roller 59. The perforations 55 provided to the laminate 51 of non-woven fabric, are preferably provided to be located toward one side of the joining portions 58 in the non-cut portions. , towards the cuts 52. The perforations 57 provided to the substrate sheet 49 are preferably formed to be located on both sides flanking the joint portions 58. If the width of the group 48 of sheet-like fibers constitute the laminate leaves 53 is less than the width of the non-woven fabrics 47a to 47c and the substrate sheet 49, as shown in figure 16, the ends of the g The sheet-like fiber rupee 48 will not be exposed at the ends 58a of the joint portion, which is preferable because it facilitates the work of inserting the support rods of the handle component (discussed below) into the components 6. of handle inserts formed by the placement of the joint portions 58 in the form of non-bulky tubes. The sheet laminate 53 in which the joining portions 58 have been formed, is cut between the joining portions 58 with a cutter roll 61, as shown in Figure 15c, forming a laminated sheet 62, to form a component of cleaning (figure 17). Next, as shown in Figure 18, one of the side portions flanking the joining portion 58 of the non-woven fabrics 47a to 47c of the sheet in the laminated sheet 62, to form a cleaning component is cut from of the perforations 55, and both side portions flanking the attachment portion 58 of the substrate sheet 49, are cut from the perforations 57. 49a in Figure 18 is the remainder of the sheet of the cut substrate 49. The sheet laminate 62 for use in the formation of the cleaning component, obtained by trimming one of the side portions flanking the connecting portion 58 of the non-woven fabrics 47a to 47c and both side portions flanking the connecting portion 58 of the substrate sheet 49, is then flexed along the joining portion 58, so that the sheet-like fiber group 48 is folded on itself as shown in Figure 19, and then the joining portion 58 is joined to become a bulky tubular component 63, as shown in Figure 20, whereby the handle insert component 6 is formed. After the handle insert component 6 has been formed in this manner, as shown in Figure 21, the laminate sheet 62 for use in the cleaning component formation is flexed so that the side of the fiber group in the form of sheet 48 it is on the internal part, and the bent portions are joined together to form the cleaning component 1. This manufacturing method differs from the first manufacturing method described above in which an insert component 6 is formed. handle in the manufacturing process, but there is substantially no difference in the structure of the resulting cleaning component 1. The second method described above was for a case in which three layers of the non-woven fabric 47a to 47c were laminated, and one layer of the sheet-like fiber group 48, but there may be only one or two layers of fabric nonwoven, or four or more layers can be used, and two or more group 48 layers can also be used. The cleaning tool of the present invention is obtained by coupling the handle component 2 to the cleaning component 1 by inserting the support rods 5, the handle component 2 into the handle insert components 6 of the component cleaning 1, manufactured as described above. The cleaning component 1 is removably coupled to the handle component 2. The material of the handle component 2 must be plastic, metal, wood, etc., but plastic is preferred because of its light weight and low cost. When the plastic is used as the material, a polyolefin resin such as a polyethylene resin or polypropylene resin is preferable because it is easy to mold. Favorable examples of the handle component 2 will now be described with reference to the drawings of Figures 22A and 22B to Figures 29A and 29B. Figures 22A and 22B to Figures 24A and 24B are examples of a preferred embodiment of the handle component 2 of the cleaning tool of the present invention. The handle component 2 comprises the support rods 5 and the fastening component 14. The support rods 5 provided to the handle component 2 are preferably formed at a spacing that is slightly wider than the spacing between the insertion openings 4 mango. With a constitution such as this, when the support rods 5 are inserted into the handle insert components 6, the spacing between the support rods 5 is narrowed, and after insertion into the handle insert components 6 , the restoring force of the support rods 5 creates an outward force, which maintains the support rods 5 securely in the handle insert components 6, so that the support rods 5 will not slide easily outwards of the handle insert components 6, during cleaning. As shown in Figures 22A and 22B the notches 15 in the form of serration are provided on the external parts of the two support rods 5. It is preferable that the notch angle a of the notches 15 on the side of the support rod 5 is a large angle, and so that the notch angle ß of the notches 15 on the side of the clamping component 14 is also a large angle. The provision of such notches 15 allows the two support rods 5 to be easily inserted with the handle insert components 6, and also makes it less likely that the support rods 5 are released from the handle insert components 6., and more effectively prevents the support rods 5 from sliding out of the handle insert components 6, during cleaning. The handle component 2 is constituted such that it can be flexed between the support rods 5 and the holding component 14, so that the support rods 5 and the holding component 14 can be fixed when they have been extended. As shown in Figures 24A and 24B, these have a receiver 16 at the base on the support rods 5, an insertion component 17 provided towards the distal end of the securing component 14, a recess 18 in which the insert 17 can be adjusted, is provided inside the receiver 16, bearing hole 21 is provided in the side walls 19 and 20 within the group 18 formed in the receiver 16, and a shaft 24 provided towards the side walls 22 and 23 of the insert component 17, is supported in the holes 21 of the bearing, which allow the clamping component 14 to rotate. A latching protrusion 26 is provided towards the ceiling 25 of the receiver 16, and a latching hollow 28 in which the latching protrusion 26 can be adjusted, is provided towards the upper surface 27 of the insert component 17. The fastening component 14 is rotated about the axis 24 until the insert component 17 enters the recess 18, and the engaging protrusion 26 within the recess 18 fits within the recess 28 of the insert component 17. This places the retention component 14 and the support rods 5 in an extended state. When the clamping component 14 is rotated in the opposite direction from above, the engaging protrusion 26 and the latching hollow 28 are disengaged, allowing the clamping component 14 and the supporting rods 5 to be folded upwards (FIG. 23). ).

The receiver 16 may rather be provided on the side of the fastening component 14, and the insertion component 17 provided on the side of the support rod 5, and the engagement protrusion 26 may be provided on the side of the insert component. 17, and the hitch hole 28 provided on the side of the receiver 16. Figures 25A and 25B illustrate yet another embodiment of the handle component 2 used in the cleaning tool of the present invention. With the handle component 2 in the embodiment illustrated in FIG. 25A, anti-slip protrusions 45 are provided instead of the notches 15 used in the previous example, to prevent the support rods 5 from being released from the insertion components 6. of mango. This handle component 2 is constituted such that the two support rods 5 and the holding component 14 can be flexed in a connecting portion 29, and the holding component 14 can be extended. The fastening component 14 of the handle component 2 shown in Figures 25A and 25B comprises an outer hole housing 46 and a core component 30 which is stored in the hollow part of the outer housing 46. The core component 30 and the housing outer 46 are formed such that it can slide in the longitudinal direction. The clamping component 14 is extended and elongated by the sliding of the outer housing 46 and the core component 30 in the longitudinal direction. A protrusion 31 is provided in the vicinity of the end of the core component 30 in the longitudinal direction, and the adjustment holes 32 and 33 in which the protrusion 31 is adjusted are provided in the vicinity of both ends of the outer housing 46 in the longitudinal direction. As shown in Fig. 25A, when the holding component 14 has been retracted, the protrusion 31 of the core component 30 fits within the adjustment hole 33 on the rear end side of the outer housing 46. As shown in the figure 25B, as the clamping component 14 is extended, the protrusion 31 of the core component 30 is adjusted and fixed in the adjustment hole 32 on the side of the distal end of the housing 46. The adjustment of the protrusion 31 within the holes of adjustment 32 and 33 fixes the fastening component 14 to the specific length. When the clamping component 14 is pulled outward, the engagement of the protrusion 31 in the adjustment hole 32 prevents the clamping component 14 from being pulled out too far, which could cause the core component 30 to come out of the outer housing 46. As shown in Figure 26A, when the protrusion 31 of the core component 40 has been fitted into the adjustment hole 32 (or 33) of the outer housing 46, the outer housing 46 is engaged to the core component 30. so that it will not move easily. The end portion of the core component 30 where the protrusion 31 is provided is formed thin as shown in Figure 26B, and when the fastening component 14 is extended and retracted, the protrusion 31 can be easily pushed into the hollow part of the outer housing 46, and the protrusion 31 disengaged from the adjustment hole 32 (or 33), by pressing on the protrusion 31 with one finger, allowing the core component 30 and the outer housing 46 to be slid relative to each other . The handle component 2 shown in FIGS. 25A and 25B is formed so that it can be bent in two at the junction portion 29 between the fastening component 14 and the support rods 5, and is provided with an anti-folding mechanism , so that during use these components will be kept extended and will not fold easily. As shown in Figures 27A and 27B, the folding mechanism comprises a stop 34 slidably formed in the longitudinal direction of the core component 30., and a latching tab 37 which extends from a side wall 36 of the attachment portion 29 of the support rods 5. The handle component 2 is prevented from collapsing during use by engaging the latch tongue 37. on the stop 34. As shown in Fig. 27A, when the stop 34 has been slid in the longitudinal direction of the core component 30 and pressed against the attachment portion 29, the fastening component 14 can be non-rotatably fixed with the clamping component 14 and the sopote rods 5, in an extended state during engagement of the latching tongue 37 on the stop 34. In contrast, as shown in FIG. 27B, when the stop 34 is slid toward the latching component. 14, the latch tongue 37 is unhooked from the stop 34, allowing the fastening component 14 to rotate about the rotational axis 38 of the attachment portion 29. The fastening component 14 can be rotated to 1802C and folded in a compact size. A movement position mechanism is formed on the stop 34, so that the stop 34 will not move more than necessary when it is slid in the direction to be disengaged from the latch tongue 37. This motion position mechanism, as illustrated in Figures 28A and 28B, for example, may be constituted such that a protuberance 39 is provided to the upper surface of the core component 30, a channel 40 which is closed on the side of the joint portion 29, is provided towards the stop 34, and the protrusion 39 can be slid into the channel 40.

As shown in Fig. 28B, the fastening component 14 is in a rotational state, so that when the stop 34 is slid in the direction to be disengaged from the latching tongue 37, the protrusion 39 hits a latching wall 41. which blocks the side of the connecting portion 29 in the channel 40 of the stop 34, so that stop 34 can no longer slide farther. With the handle component 2 shown in Figures 25A and 25B, the support rods 5 and the holding component 14 can not be flexed when extended, as shown in Figures 29A and 29B, a hemispherical protrusion 43 is provided to the bottom 42 of the attachment portion 29, a hemispherical recess 44 for adjustably supporting the hemispherical protrusion 43 is provided to the core component 30, and when the fastening component 14 and the support rods 5 have been extended, as shown in Figs. 29A, the hemispherical protrusion 43 of the connecting portion 29 fits within and is fixed in the hemispherical recess 44 of the core component 30. In contrast, when the handle component 2 is to be folded upwards, as shown in Fig. 29B, the fastening component 14 is rotated by applying a slight force to it, after which the hemispherical protrusion 43 of the bottom 42 d e the joining portion, leaves the hemispherical recess 44 of the core component 30, allowing the clamping component 14 to be rotated and the support rods 5 and the clamping component 14 to be bent in two. The cleaning component 1 of the cleaning tool of the present invention can also be of a disposable type, in which case the cleaning component 1 can be removed from the handle component 2 after use and replaced with a new cleaning component 1 .

POSSIBILITY OF INDUSTRIAL APPLICATION The present invention can be used to take advantage in the domestic field and elsewhere, as a cleaning tool to remove dust that has accumulated on trunks or other furniture: computers, release devices, and other electrical products; and interior walls, thresholds and sills, mounds and the like.

It is noted that in relation to this date, the best method known to the applicant to carry out the aforementioned invention is that which is clear from the present description of the invention.

Claims (13)

CLAIMS Having described the invention as above, the content of the following claims is claimed as property:

1. A cleaning tool comprising a cleaning component and a handle component, characterized in that the cleaning component is designed such that a group of sheet-like fibers and a sheet are joined together to produce a sheet laminate having a portion of When this laminated sheet is bent along the joining portion to form a bulky component forming portion, the sheet laminate in which the bulky component forming portion has been formed is flexed so that forming portions of the bulky component are crossed with each other, and integrated such that the contact surfaces of the sheet-like fiber groups are bonded together, and the supporting rods of the handle component are inserted into a component handle insert having handle insert openings made in one end of the bulky and shaped component forming portions as well as within the bulky component forming portion.

2. A cleaning tool comprising a cleaning component and a handle component, characterized in that the cleaning component is designed such that a group of fibers in the form of a sheet and a sheet having a strip component are partially joined to produce a laminate of sheet having a joining portion, this sheet laminate is flexed along the joining portion to form a bulking component forming portion, the sheet laminate into which the forming portion of the bulky component has been formed. it is flexed so that the forming portions of the bulky component are crossed with each other, with the side of the group of fibers in sheet form on the inner side, and integrated such that the contact surfaces of the fiber groups in the form of sheet are joined together, and the support rods of the handle component are inserted into a handle insert having openings of handle inserts made at one end of the bulking component forming portions and formed within the bulking component forming portion.

3. The cleaning tool according to claim 1 or 2, characterized in that the group of fibers in the form of a sheet is formed by placing layers of a plurality of groups of fibers in sheet form. The cleaning tool according to claim 3, characterized in that the group of fibers in the form of a sheet comprises a first group of fibers in the form of a sheet composed of numerous fibers and a second group of fibers in the form of a sheet composed of fibers thicker than the fibers that make up a first group of leaf-shaped fibers. The cleaning tool according to claim 1, characterized in that the group of fibers in sheet form is constituted such that a first group of fibers in the form of a sheet composed of numerous fibers and a second group of fibers in the form of a sheet composed of fibers that are thicker and shorter than the fibers that make up the first group of sheet-like fibers, are partially joined. The cleaning tool according to claim 1 or 5, characterized in that the cleaning component is produced by interposing a body of the fiber group composed of a first group of fibers in sheet form and / or a second group of sheet-like fibers, between the groups of sheet-shaped fibers that are facing each other when a sheet laminate is flexed, and joining the body of the fiber group and the group of sheet-like fibers where these they are in contact with one another. 7. The cleaning tool according to claim 1, characterized in that the sheet laminate is produced by sandwiching the group of sheet-like fibers with the sheet, and joining the sheet body to the sheet-like group of fibers to cover the surface on the opposite side at the site. of the joint portion. The cleaning tool according to claim 4 or 5, characterized in that the group of fibers in the form of a sheet comprises a plurality of first groups of fibers in the form of a sheet and / or a plurality of second groups of fibers in the form of sheet. 9. The cleaning tool according to claim 8, characterized in that the group of fibers in the form of a sheet is produced by alternating lamination of the first groups of fibers in sheet form and of the second groups of fibers in sheet form. . The cleaning tool according to any of claims 1 to 9, characterized in that the sheet is composed of a non-woven fabric. A method for manufacturing a cleaning component for a cleaning tool, characterized in that a group of sheet-like fibers produced by grouping the fibers in the form of a sheet is laminated with a sheet having a strip component , these are partially joined to form a sheet laminate, and the sheet laminate is then flexed along its joining portion, so that the group of sheet-like fibers is folded into the joint portion, thereby which produces a portion of formation of the bulky component after which the sheet having the strip component is flexed back towards the group of fibers in sheet form on the opposite side, to thereby surround the forming portion of the component In addition, the bulky component formation portion is flexed so that the side of the sheet-like fiber group is on the inside, and the fiber-shaped group is The sheet and the sheet having the strip component are joined and integrated so that the contact surface of the sheet-like groups of fibers are joined to one another. A method for manufacturing a cleaning component for a cleaning tool, characterized in that it comprises the steps of: notching to form a strip on a long sheet used to form a sheet having a strip component; the formation of a joining portion, by joining, in the direction of the width of the sheet, a long laminated sheet obtained by rolling a long sheet which has been underwired for the formation of a strip, firstly with a group of fibers in long sheet form, produced by grouping the fibers in the form of a sheet, and then with a sheet of substrate to support the sheet-like group of fibers; obtaining a laminated sheet to form a cleaning component, by splitting the longleaf laminate between the joint portions; the formation of a bulky component forming portion by cutting one of the side portions flanking the connecting portion of the sheet having a strip component, into the laminated sheet to form a cleaning component, by cutting both flanking side portions the binding portions of the substrate sheet, and then flexing along the joining portions so that the group of sheet-like fibers is bent, and joining so that the joining portions become a bulky tube shape; and the formation of handle insertion openings, at one end of the bulky component forming portion upon flexing the laminated sheet to form a cleaning component in which the bulky component forming portion has been formed, so that groups of sheet-shaped fibers are on the inner part, and integrating so that the contact surfaces of the sheet-like fiber groups are linked with one another. The method for manufacturing a cleaning component for a cleaning tool according to claim 11 or 12, characterized in that the connection is made by thermal fusion.