System and method for moulding a tufted body with a curved outer surface

Abstract

A mould system for producing a tufted body having a curved outer surface, for example one hemispherical half of a spherical toothbrush head, the mould system comprising a mould form having a receptacle and an annular flange circumscribing an open end of the receptacle and at least one slot formed substantially radially in the flange and extending into a sidewall of the receptacle.

Claims

1. A method of moulding a tufted body having a curved outer surface, the method comprising the steps of: inserting one or more tufts from one or more spools into a receptacle of a mould form such that each tuft projects outwardly from the receptacle; forming a moulded body within the receptacle in which at least a portion of each tuft is embedded for retention, wherein the one or more tufts remain strung to the one or more spools as the moulded body is moulded; and removing the tufted body from the mould form, wherein the step of ejected the tufted body from the mould form draws a fresh length of tufts from the spools into the interior of the receptable for the next moulding thereby consecutively moulding multiple tufted bodies, wherein the mould form comprises a flange circumscribing an open end of the receptable and having one or more slots formed in the flange and extending into the receptacle, the method comprising allowing a tuft to pass through each slot as the tufted body is removed from the receptacle.

2. The method of claim 1 comprising the step of melting the portion of the tufts located within the receptacle to at least partially form the moulded body.

3. The method of claim 1 comprising the step of injecting a polymer into the receptacle in order to at least partially form the moulded body.

4. The method of claim 1 comprising the step of retaining at least some of the tufts in a predefined location while the moulded body is formed.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention will now be described with reference to the accompanying drawings, in which:

(2) FIG. 1 illustrates a perspective view of a moulding system according to a preferred embodiment of the invention;

(3) FIG. 2 illustrates a perspective view of a mould form which is a component part of the mould system illustrated in FIG. 1;

(4) FIG. 3 illustrates a schematic representation of the configuration of an array of tufts as inserted into a hollow receptacle of a mould form which is part of the mould system of the invention;

(5) FIG. 4 illustrates a schematic side elevation of the mould form shown in FIG. 2; and

(6) FIG. 5 illustrates a brush head formed with a tufted hemisphere as produced with the system and method of the invention.

DETAILED DESCRIPTION OF THE INVENTION

(7) Referring now to the accompanying drawings, there is illustrated a mould system, generally indicated as 10, for producing a tufted body B having a curved outer surface from which an array of tufts T project, the tufted body B being, in a preferred embodiment, hemispherical in shape for use as a brush head or part thereof for an electric toothbrush or the like. The mould system 10 and accompanying methodology may however be utilised to produce tufted bodies of various shape and/or size, as will become apparent from the following description of the configuration and operation of the mould system 10.

(8) The mould system 10 comprises a mould form 12 to be used in producing the tufted body B, preferably by means of injection moulding as described hereinafter, the body B taking the form, in the embodiment illustrated, of a hemispherical brush head as illustrated in FIG. 5. The body 12 thus has the array of tufts T projecting outwardly therefrom and the body B can then be driven, mechanically or electrically, about a central axis in order to effect a continuous brushing motion. The mould form 12 comprises two main components, a hollow receptacle 14 which defines the shape of the tufted body B, and in the embodiment illustrated is hemispherical in form, and an annular flange 16 which extends radially outwardly from an open end or rim of the receptacle 14.

(9) In order to allow the array of tufts T to be captured within the tufted body B the receptacle 14 is provided with an array of apertures arranged in rows 18, 20, 22, 24 therein, the functionality of which will be described in greater detail hereinafter. In the embodiment illustrated it is desired to provide the tufts T in an array of rows about the body B, and thus the apertures are provided as a first row 18 immediately adjacent the flange 16, a second row 20 beyond the first row 16, a third row 22 beyond the second row 20, and an uppermost row 24. Each of the apertures in the rows 18, 20, 22, 24 are preferably angled or aimed towards a centre of the hemisphere defined by the receptacle 14, such that each of the tufts T, when inserted into the apertures 18, 20, 22, 24 will project substantially normally from the outer surface of the tufted body B in order to provide a substantially even distribution of the tufts T about the exterior of the body B as illustrated in FIG. 5. It will however be appreciated that the apertures 18, 20, 22, 24 may be arranged in any other desired configuration and orientation in order to provide a desired arrangement of the tufts T about the body B.

(10) In order to facilitate both the insertion and subsequent removal of the tufts T, in particular from the first row 18 and second row 20 of apertures, the flange 16 comprises an array of slots 26 extending radially outwardly from the receptacle 14, at least some of the slots 26 being coincident with apertures in the first row 18, while at least some of the other slots 26 are coincident with apertures in the second row 20, as can be seen for example in FIGS. 1 and 2, and as will be described in detail hereinafter.

(11) Turning then to the operation of the mould system 10, the mould form 12 is located in a suitable moulding apparatus (not shown), preferably but not essentially with the flange 16 lying in a substantially horizontal plane and the receptacle 14 curving upwardly from the flange 16, as orientated in FIG. 1. The mould system 10 further comprises retention members in the form of an opposed pair of first retention members 28 and an opposed pair of second retention members 30 vertically spaced above the first retention members 28 with respect to the described orientation of the mould system 10. The retention members 28, 30 are positioned with one member 28, 30 on opposed sides of the mould form 12 and are displaceable between a disengaged state as illustrated in FIG. 1, in which the mould form 12 is fully accessible, and an engaged position in which the retention members 28, 30 abut against the exterior of the receptacle 14, preferably in the region of the first row 18 and second row 20 of apertures as hereinafter described.

(12) The moulding process begins with locating the retention members 28, 30 in the disengaged position as illustrated in FIG. 1, and inserting a tuft T into each of the apertures of the rows 18, 20, 22, 24. The tufts T are preferably dimensioned in length to pass into the interior of the receptacle 14 and extend outwardly from the lower open end thereof, while also projecting the required distance outwardly from each of the apertures 18, 20, 22, 24 in order to define the tufts T of bristles in the finished tufted body B. When inserting the tufts T into the apertures of the first row 18 and second row 20 the tufts may be initially inserted in a outer region of the slots 26 and the tufts T then displaced radially inwardly towards the respective aperture 18, 20 with which the slot 26 is coincident, whether in the first row 18 or second row 20.

(13) At this point the pair of second retention members 30 are displaced into the engaged position abutting against the exterior of the receptacle 14, and preferably immediately beneath the apertures of the second row 20. As the abutting end of the retention members 28, 30 are shaped to closely conform to the exterior of the receptacle 14, the second retention members 30 will thus effectively form a thin ring surrounding the receptacle 14 immediately below the apertures in the second row 20, and will therefore act to retain the respective tufts T in register with those apertures of the second row 20, preventing the tufts T from migrating back down along the corresponding slots 26. With the second retention members 30 in the engaged position, the first retention members 28 can then be advanced into the engaged position abutting against the exterior of the receptacle 14, immediately beneath the apertures in the first row 18. Similar to the second retention members 30, the first retention members 28 will hold the tufts T in position in the apertures of the first row 18, preventing migration along the respective slots 26.

(14) At this point all of the tufts T are retained in the desired position and orientation, in order to allow moulding of the body B. The body B may be formed by melting the portion of the tufts T located within the receptacle 14, and optionally that length of tufts T extending downwardly from the open end of the receptacle 14. It may also be necessary or desirable, depending on the suitability of the material from which the tufts T are manufactured, to injection mould additional polymer material (not shown) into the receptacle 14 in order to form the body B. If the tufts T within the receptacle 14 are not melted to form part of the mass of the body B, the additional length of tufts T extending downwardly from the open end of the receptacle 14 are severed or otherwise removed. Once the molten polymer within the receptacle 14 has cooled and hardened the tufted body B can then be removed from the mould form 12.

(15) This process involves firstly withdrawing the retention members 28, 30 into the disengaged state, and then effecting relative vertical displacement between the tufted body B and the mould form 12 in order to release the tufted body B. As the tufts projecting outwardly through the apertures in the third row 22 and fourth row 24 have a significant vertical component of their orientation they will, with minor resilient deformation, pass unhindered through the respective aperture 22, 24 as the mould form 12 and tufted body B are separated from one another. However, the tufts T projecting from the first row 18 and second row 20 have a significant horizontal or radially extending component relative to the receptacle 14, but are nevertheless permitted to pass through the mould form 12 by means of the slots 26. As the slots 26 extend upwardly into the apertures of both the first row 18 and the second row 20 the corresponding tufts T can pass downwardly from the respective aperture into the associated slot 26 as the mould form 12 and tufted body B are vertically separated from one another. Thus the tufted body B can be separated from the mould form 12 without complication.

(16) If, as would be the case in a commercial moulding process, it is intended to consecutively mould multiple tufted bodies B, the above process can be slightly modified in order to facilitate a more efficient moulding process. The tufts T fed into the various rows of apertures 18, 20, 22, 24 may be fed in continuous form, for example from a number of spools (not shown) of the tuft material, and remain strung to the spool as the body B is moulded. As a result, the act of ejecting that moulded body B from the mould form 12 will draw a fresh length of the tufts T off the spools or other store (not shown) into the interior of the receptacle 14 in preparation for moulding the next body B. The process can be repeated continually.

(17) It will therefore be appreciated that the mould system 10 and corresponding method of moulding of the present invention permit a tufted body B having a curved outer surface to be quickly and easily moulded and released, in order to produce what would otherwise be a relatively complex moulded tufted body B.

(18) The invention is not limited to the embodiment described herein but can be amended or modified without departing from the scope of the present invention.