EP2587959B1 - Process and apparatus for producing brushes - Google Patents

Description

The invention relates to a method and an apparatus for producing brushes.

Various methods of making brushes are known. Conventionally, a brush body is provided with an array of holes ("hole pattern" or "hole pattern") corresponding to the desired arrangement of bristles. Bundles or tufts of bristles are then inserted into the holes of the brush body and anchored therein by means of impressed small metallic anchors or by means of loops.

In an alternative method of making brushes which has become established within a few years, to which the present invention pertains, and which is referred to as Anchor Free Tufting (AFT), the bristle tufts become small Brush head plate (hereinafter referred to as "base part") attached without the use of loops or anchors, and the base part is then inserted or fixed in a brush body or a handle. In a variant of the AFT method brush handles are made with a hole pattern that corresponds to the desired tuft pattern. Bristle tufts are then inserted into these holes and attached to the brush handles. The attachment ends of the tufts are then covered with a small plate. This base part becomes part of the brush itself after the backside injection of plastic material.

An important and expensive step in the manufacture of brushes is the so-called bristling of the base part. In this case, a metal carrier part (perforated plate called) used in the Beborstungsmaschine which has the same hole pattern as the base part and which serves as a guide and part holder for the bristle tufts. This carrier part is transported together with the bristled base part to the injection mold and acts there as Section of a mold half, which limits the cavity into which is injected with a second mold half.

The bristle and the injection molding tool are coupled via the support plates with respect to the flow of material and timed to each other.

For example, the shows EP 1 864 588 A2 a method of making brushes using a prefabricated backing plate to which bristle tufts are attached. This carrier plate later forms a portion of the finished brush. The carrier plate is located during production in a perforated field plate and is used together with this perforated field plate in an injection mold to inject a brush portion on the back of the carrier plate. In this case, the use-side ends of the bristle bundles lie in a mold cavity of the mold surface of the injection mold and the edge of the support plate rests on the edge of the perforated field plate.

The object of the invention is to provide a flexible and cost-effective production of brushes.

1. a) Vorsehen entweder wenigstens eines vorgefertigten Basisteils, an dem Borstenbüschel befestigt sind und das einen Abschnitt der fertigen Bürste bildet, wobei am Basisteil rückseitig eine separate Stützschicht aufgebracht ist oder wenigstens eines vorgefertigten Basisteils, das durch Umspritzen von mehreren Borstenbüscheln mit zuvor miteinander verschmolzenen Borstenenden gebildet ist,
2. b) Zuführen und Positionieren des beborsteten Basisteils zu bzw. in einem Spritzgusswerkzeug, wobei jedes Basisteil in einer Kavität einer Formhälfte des Spritzgusswerkzeugs mit seinem Rand am Rand einer von der zugeordneten Kavität ausgehenden Öffnung aufliegt und die Borstenbüschel in die Öffnung ragen, und
3. c) rückseitiges Anspritzen eines Bürstenabschnitts an das Basisteil.

This object is achieved by a method for producing brushes by means of a device, which is characterized by the following steps:

1. a) providing either at least one prefabricated base part, are attached to the bristle tufts and forms a portion of the finished brush, wherein the base part back a separate support layer is applied or at least one prefabricated base part formed by molding over several bristle tufts with previously fused bristle ends is
2. b) feeding and positioning of the bristled base part to or in an injection mold, wherein each base part rests in a cavity of a mold half of the injection mold with its edge on the edge of an opening of the associated cavity opening and the bristle tufts protrude into the opening, and
3. c) back-injection of a brush portion to the base part.

The feeding and positioning of the bristled base parts to or in one

Injection molding tool is preferably fully automatic.

The device according to the invention for producing brushes, in particular with a method according to the invention, is characterized by an injection mold having a mold half with at least one cavity for receiving a bristled base part, wherein the cavity has an opening for receiving a plurality, preferably all bristle tufts, and one the opening surrounding Abstützrand for supporting and supporting the base part. Since the base part rests on the side of the mold half and this has inwardly of the edge an opening, the base part is not in contrast to the prior art is supported over the entire surface, but is inward of the edge preferably completely or at least largely unsupported.

By the invention, the effort required for the production of the carrier plates, significantly reduced because the carrier plates no longer migrate to the injection molding tool, whereby the timing of injection molding and bristle machine no longer necessarily be coupled together. The method according to the invention thus provides for a hole plate-free feeding, positioning and back-molding of the base part. In the injection molding tool is no elaborate perforated plate with numerous openings whose number corresponds to the number of openings in the base part, more available. This perforated plate was previously used in the injection mold as a support for the relatively thin base plastic, to absorb the injection pressure. In the method according to the invention and in the device according to the invention, however, an opening (preferably a single opening) in the region of the cavity to be ejected is provided in a mold half of the injection molding tool into which the plurality of bristle tufts protrude. The base part is preferably exclusively or almost exclusively only with its peripheral edge on the edge of the opening extending from the cavity and is preferably supported only at this edge.

In order to withstand the injection pressure, according to an alternative prior to injection molding, a back-injection molding of a separate support layer is provided, which forms a prefabricated unit with the bristled base part and leads to an increased flexural rigidity.

The other alternative according to the invention provides for the bristle ends of the bristle tufts to first fuse together, which usually takes place in a perforated plate which is equipped with the bristle tufts and is expensive to produce. Subsequently, this perforated plate is transported in an injection mold to overmold the tufts. This results in a plate-like base part, in which the bristle tufts are positively and securely embedded at their point of fusion. In the state of the art, this base part has always also been, together with the carrier plate or perforated plate, in another injection molding tool or another station of an injection molding tool transported. The carrier plate served to support against the injection pressure during injection molding of the brush body (head and stem). However, the present invention provides that these provided with the hole pattern of the brush carrier plates when making the brush body no longer provide as support plates in the injection mold. Here too, as described above, the base part is now supported on the edge of an opening in a cavity of the mold half. The tufts protrude into the opening, which is very easy to produce due to their size. The encapsulation of the tufts results in a very stable plate (base part), which can withstand the injection pressure, although here too the base part inwards of the edge is not supported or at least largely unsupported.

The invention relates, as stated, a nontacky production of brushes. The bristle tufts are not individually held in holes of a perforated plate by lateral interference fit in contrast to the perforated plate in injection molding, but protrude freely in the opening of the mold half and are held by the base part.

The base part is held on the edge in the cavity.

According to the preferred embodiment, the base part lies with its edge closed circumferentially on the likewise closed circumferential edge of the opening, so that a sealing effect is achieved.

The injection molding of the support layer takes place in a separate device or station, which is passed through before the final injection molding in the aforementioned mold half.

By the method according to the invention, in which the perforated plates no longer circulate between the boring machine and the injection-molding tool, the entire production and the entire apparatus can manage with significantly less perforated plates.

Of course, it should be possible to accommodate a plurality of base parts per perforated plate, that is, a plurality of adjacent cavities and possibly also positioned in a plurality of rows are provided per perforated plate.

It is now also possible to store the bristled base parts (before or after the application of the support layer) in a temporary storage or buffer storage. During maintenance work on the injection molding tool or the bristle machine, therefore, it does not come to a standstill of the other machine, which significantly increases the overall flexibility. In addition, the bristled base parts can also be purchased.

According to the preferred embodiment, the base parts remain support-free in the region of the opening during spraying. Alternatively, punctiform or linear support projections may press in the opening against the base member to support it during injection molding.

One of the preferred embodiments provides in this case that the support extensions to the base part conical, preferably even tapered. This allows them to slide between adjacent bristles without damaging the bristles.

According to a preferred embodiment, the tufts of the tufts projecting from the rear side (rear side with respect to the bristles is the side with the fixed ends of the bristles) are glued or melted, e.g. by hot air, heat radiation or contact heat (pressing a hot tool). The contacting and flattening of the liquefied tuft ends is advantageous in that a dense, preferably closed surface of molten plastic is formed. This tightness is advantageous for the subsequent injection molding.

The support layer is preferably applied flat, that is, in the preferred embodiment, even over the entire surface. At most, the edge of the base part, with which it rests against the mold half, remains uncovered.

However, the support layer can also be formed in that the still unsecured bristle tufts are attached to the rear side by encapsulation by means of the support layer. In this embodiment, the step of applying the support layer simultaneously serves to attach the tufts to the base part.

Since the bristle tufts partially extend to near the edge of the base part, it may be advantageous to use a so-called insertion tool on To use injection molding tool. This insertion tool pushes the bristles slightly inwardly and together to facilitate easier insertion of the bristles into the common opening of the mold half. As a result, no bristles can get stuck on the edge of the opening and bend.

As already mentioned above, it is preferable to have a plurality of cavities in the mold half of the device according to the invention in order to increase the discharge rate of the entire device.

The mold half with the at least one cavity can also, and this is preferably formed in several parts. A first and a second molded part, if appropriate also further molded parts with in particular a plurality of juxtaposed cavities or rows of cavities, can be used. The cavity associated with a brush is then divided into several sections, for example into a section in the first and into a section in the second shaped part. These cavities merge into one another and form the total cavity of the mold half. However, the first molded part is separable from the second molded part and serves as a means of transport for or sitting in it base parts. Thus, the first molded part can be fitted independently of the second molded part first with the bristled base parts and only then be coupled to the second molded part, namely immediately prior to injection molding. However, since the first molded part is very easy to produce due to the lack of hole pattern, many first molded parts can be manufactured and used relatively inexpensively, which significantly improves the cycle time and flexibility of the entire device.

A separation station between the bristle machine and the injection molding tool can be provided to quickly clear the bristle machine again for equipping with base parts still to be bristled.

A coating tool, which may also be embodied as a single station in the then multi-station injection molding tool, should be positioned between the bristle machine and the injection molding tool, that is, possibly the station where the aforementioned spattering of the coated, bristled base part occurs. In this Coating tool or in this coating station, the support layer is applied.

It should be emphasized that, according to the preferred embodiment, the so-called brush body is injection-molded in the injection molding tool, which can be designed in one or more parts. This brush body is usually the brush handle, the brush neck and a part of the brush head. The other part of the brush head is formed by the base part.

However, an embodiment is also conceivable, in particular for less expensive brushes, in which the base part itself already has almost the entire head and essentially the entire handle or handle of the brush. This base part is then covered on the back in several steps at least in the region of the head, namely first with the support layer in the region of the already fastened tufts and with an injection-molded cover-like part which covers the support layer. Of course, this part also forms a brush section.

• Figur 1 eine perspektivische Draufsicht auf eine Beborstungsmaschine, die Teil der erfindungsgemäßen Vorrichtung zur Herstellung von Bürsten sein kann;
• Figur 2 eine Draufsicht auf eine Lochplatte, die bei der Beborstungsmaschine nach Figur 1 eingesetzt wird;
• Figur 3 die Lochplatte nach Figur 2 mit eingesetzten Basisteilen vor dem Beborsten;
• Figur 4 die Ansicht nach Figur 3 mit beborsteten Basisteilen;
• Figur 5 einen nach dem Beborsten folgenden Verfahrensschritt zum Verschmelzen der Borstenenden;
• Figur 6 ein noch offenes Beschichtungswerkzeug, bei dem die beborsteten Basisteile rückseitig mit einer Stützschicht versehen werden;
• Figur 7 das Beschichtungswerkzeug nach Figur 6 mit entferntem Oberteil nach dem Aufbringen der Stützschicht;
• Figur 8 einen darauffolgenden Verfahrensschritt, bei dem die beborsteten Basisteile den Lochplatten entnommen werden;
• Figur 9 eine Draufsicht auf ein Formteil eines Spritzgusswerkzeugs als Teil der erfindungsgemäßen Vorrichtung;
• Figur 10 eine alternative Ausführungsform zu Figur 9, bei der zusätzlich Abstützfortsätze in die Öffnung des Formteils hineinragen;
• Figur 11 eine perspektivische Draufsicht auf ein Unterteil der erfindungsgemäßen Vorrichtung im Bereich des Spritzgusswerkzeugs kurz vor dem Einsetzen der beborsteten Basisteile;
• Figur 12 die in ein Formteil eingesetzten Basisteile;
• Figur 13 eine Unteransicht des Formteils nach Figur 12;
• Figur 14 eine perspektivische Ansicht der erfindungsgemäßen Vorrichtung im Bereich des Spritzgusswerkzeugs beim Einsetzen des ersten Formteils in ein zweites Formteil;
• Figur 15 das geöffnete Spritzgusswerkzeug nach Figur 14 nach dem Spritzvorgang; und
• Figur 16 bis Figur 19 mehrere Verfahrensschritte einer geringfügig modifizierten Ausführungsform der Erfindung mit modifizierter Vorrichtung.

Further features and advantages of the invention will become apparent from the following description and from the following drawings, to which reference is made. In the drawings show:

• FIG. 1 a top perspective view of a bristle machine, which may be part of the device according to the invention for the production of brushes;
• FIG. 2 a plan view of a perforated plate in the bristle after FIG. 1 is used;
• FIG. 3 the perforated plate after FIG. 2 with inserted base parts before the bristles;
• FIG. 4 the view after FIG. 3 with bristled base parts;
• FIG. 5 a subsequent step after Beborsten for fusing the bristle ends;
• FIG. 6 a still open coating tool, in which the bristled base parts are provided on the back with a support layer;
• FIG. 7 the coating tool after FIG. 6 with the top removed after the application of the backing layer;
• FIG. 8 a subsequent process step, in which the bristled base parts are removed from the perforated plates;
• FIG. 9 a plan view of a molded part of an injection molding tool as part of the device according to the invention;
• FIG. 10 an alternative embodiment to FIG. 9 in which supporting projections additionally protrude into the opening of the molded part;
• FIG. 11 a perspective top view of a lower part of the device according to the invention in the region of the injection mold shortly before the onset of bristled base parts;
• FIG. 12 the base parts used in a molding;
• FIG. 13 a bottom view of the molding after FIG. 12 ;
• FIG. 14 a perspective view of the device according to the invention in the region of the injection mold when inserting the first molded part in a second molded part;
• FIG. 15 the opened injection mold after FIG. 14 after the injection process; and
• FIG. 16 to FIG. 19 several process steps of a slightly modified embodiment of the invention with a modified device.

In FIG. 1 a so-called perforated plate 10 of a device consisting of several tools and stations for the production of brushes is shown. The perforated plate 10 is made of metal and preferably has a plurality of very precisely produced cavities 12, in which prefabricated base parts 14 of brushes, here toothbrushes, are inserted. The base parts 14 are used for anchorless attachment of bristle tufts. The base parts 14 have a peripheral, parked up edge and a hole pattern for filling by the bristle tufts. The cavity 12 has a corresponding hole pattern. The production of such a cavity with hole pattern is very complicated and usually takes place by wire erosion or jig grinding.

In the so-called bristle machine, the base parts are then filled with the bristle tufts, as for example in the EP 0 972 465 B1 is shown. The perforated plate 10 serves as a transport body and also for storage and guidance of the bristle tufts, which protrude into the corresponding holes in the perforated plate. The portion of the bristle tufts protruding into the holes is the part of the bristles that later protrudes from the brush.

In FIG. 2 the hole pattern of the perforated plate 10 can be seen from above.

FIG. 3 shows the base parts 14 inserted into the corresponding cavities 12, wherein it can be clearly seen that the base parts 14 are received exactly and accurately in the cavities 12. There are numerous perforated plates are provided in the bristle machine, which are preferably equipped in or outside the bristle machine with the base parts and then beborstet. The perforated plates 10 are finally transferred after the bristle machine in another machine or in another station, including the bristled base parts contained therein, in order to carry out a further processing step can.

FIG. 4 shows the bristled base parts 14 in the perforated plate 10, wherein the bristle tufts 16 protrude with its rear end relative to the base member 14 upwards.

As already explained, it is ensured either in the bristle machine itself in a separate station or outside thereof in a fastening station that the bristles are fastened together at their protruding ends 16 and also connected to the base part 4. This is done for example by means of thermal bonding of the protruding ends of the tufts 16 by hot air, radiant heat and / or by contact heat.

At the in FIG. 5 illustrated embodiment, an electrically heated tool with a plurality of heated punches 18 is provided, which are connected to a power source 20.

The cross section of the punches 18 is adapted to the circumscribed by the edge of the corresponding base part 14 cross section.

Either the bristle ends 16 are previously already heated and brought to melting temperature, so that they stick together, or the stamp 18 are moved down against the bristle ends 16 and then bond them by fusing.

Of course, the bristle ends 14 may also first be brought to temperature and fused without the punches contacting them. Only then are the rams 18 moved down to flatten the liquid plastic mass of the molten ends, so that a possible closed plastic layer 22 results from the molten material of the tufts. Although it is advantageous that a flat, closed layer 22 results on the back of the base member 14, but this is not mandatory. There could just as well be individual thickenings of bristle tufts 16, which result from the fusing of the individual bristles of a bristle tuft.

FIG. 6 shows another tool that can also be designed as a station of a larger device. This is a so-called coating tool.

The bristled base parts 14 located in the perforated plate 10 are preferably still in the perforated plate 10 to the in FIG. 6 Transported coating tool shown and inserted there in a lower part 24 of an injection molding tool. An upper 26 with adapted cavities 28 on its underside may be moved downwardly against the base 24 to close the cavity 28 downwardly through the corresponding base 14 so as to provide a cavity. In the corresponding cavities, a plastic compound is then injected, which covers the back of the bristled base member 14 preferably completely, if necessary, except for the peripheral edge. This applied layer is a support layer 30, which gives the unit of base part 14 and bristle tufts 16 a higher rigidity. The support layer 30 is in FIG. 7 to recognize.

In the next step, see FIG. 8 , the intermediates produced are removed from the perforated plates 10 in a separation station. These intermediates can be stored in a store or stored unsorted, or they can immediately after their removal from the perforated plate 10 to a another machine, namely the below-explained injection molding tool to be transported.

The injection mold is in FIG. 14 to recognize. It essentially comprises a lower mold half 40 and an upper mold half 42, each having cavities which merge into each other in the closed state of the tool and form a cavity to be ejected. The lower mold half 40 comprises at least two parts, namely a first mold part 44, which the aforementioned and in FIG. 8 and a second mold part 46. The first mold part 44 is shown in FIG FIG. 9 good to see from above. It has a plurality of cavities 46, from each of which an opening 48 extends, which serves to receive the bristle tufts 16 of a base part 14. The edge 50, which is recessed and part of the cavity 46, surrounds the respective opening 48. This edge 50 serves as a supporting and supporting surface for the bristled base part 14. In addition to the edge 50, the cavity 46 also has a neck portion 52 as a transition between brush head and later still shown brush handle.

This neck portion 52 is how FIG. 14 shows, in the stem of the brush defining portion 56 of the cavity in the second mold part 46 via.

In FIG. 11 It can be seen that the first molded part 44 is fitted with the prefabricated intermediate products by using an insertion tool 58, which can consist of a plurality of plates to be moved on one another. This insertion tool 58 may also be provided in the form of a funnel. The insertion tool 58 serves to push the bristle tufts 16 inwardly towards each other to prevent abutment of the marginal bristles on the edge 50. However, prior to complete introduction of the intermediates into the corresponding cavity and opening 46, 48, the insertion tool 58 is removed.

The assembly of the first molded part 44 can preferably be done outside the injection molding tool or in a lying before the injection molding station in the injection mold, as for example in the so-called helicopter tools according to eg DE 195 15 294 A or dice tools according to eg WO 2007/085063 the case is. With such tools, the assembly can take place during the injection process, with the tool closed. Alternatively, the assembly can take place in an open tool between two injection cycles. In this case, you lose some cycle time, as the tool must remain open a little longer after an injection cycle, until the assembly is completed.

In FIG. 12 is the assembled first molded part 44 to be seen from above, in FIG. 13 from underneath. It can also be seen that the tufts 16 hang freely cantilevered in the opening 48.

The first mold parts 44 form transport parts for the bristled base parts 14 and transport them corresponding to the associated second mold parts 46. These mold parts 46 have a recess 60 into which the molded part 44 is inserted accurately. Subsequently, the injection mold is closed, and the injection molding process can take place.

After opening the injection molding tool (see FIG. 15 ), the first mold part 44 with the molded-on brush body 62 is removed from the injection mold, and the finished brushes are separated from the first mold part 44.

Of course, it would also be possible to inject several components one behind the other by the injection molding machine has even more stations for the other components. Again, the first mold part 44 serve as a means of transport between the stations.

In the injection molding process, in the aforementioned embodiment, all the injection pressure in the area of the base part 14 is received exclusively at the edge of the base part 14, with which it contacts the edge 50.

As an alternative to this, it would also be possible to provide support extensions 70 projecting from a bottom of the opening 48 or starting from the second shaped part 46 in the region of the recess 60, projecting upwards into the opening in the direction of the base part 14. The support extensions 70 are linear or, as shown, selective support points and preferably run conically towards the base member 14 in order to push between bristles can.

In the embodiment of the FIGS. 16 to 19 the base part is not made before the welding of the bristle ends, but afterwards. First In a bristle tool bristle tufts 16 are inserted into holes of a perforated plate 10 with a corresponding cavity 80 for the later to be produced base part ( FIG. 16 ). The upwardly projecting bristle ends of the bristle tufts 16 are first fused together. Subsequently, this perforated plate 10 is transported in an injection mold to overmold the tufts 16. If the bristle ends are fused to a flat plastic plate and not to a ball-like thickening, the base member 14 is essentially only sprayed on, but should also fall under "encapsulation". This results in a plate-like base part 14 ( Figures 16 and 17 ), in which the bristle tufts 16 are embedded more or less positively and securely at their thickened point of fusion 82 (see cross-sectional view in FIG FIG. 18 ). The present invention provides that these provided with the hole pattern of the brush perforated plates 10 in the subsequent production of the brush body (head and stem of the brush) no longer provide as support plates in the injection mold.

The bristled base parts 14 are rather separated from the perforated plates 10 ( FIG. 19 ) and either fed to a previously described storage / buffer and later or immediately according to the FIGS. 9 to 15 further processed. The bristled base parts 14 must therefore be inserted into the first mold parts 44 (eg fully automatically), in order then to be transported to the injection molding tool. The injection molding process is carried out as described in the first Ausführungsbeipiel.

Again, the base part is supported at the edge of an opening 48 in a cavity 46 of the mold half. The brush 16 protrude into the opening 48, which is very easy to produce due to their size.

For all embodiments applies: The device for producing brushes may consist only of the injection molding tool or alternatively also from other tools such as the bristle tool and / or in the FIGS. 6 and 7 shown coating tool. Separation stations and placement stations between individual tools or stations can be provided in which intermediate products of tool parts or carrier parts are removed or inserted into them.

Claims (14)

1. A method for producing brushes by means of an apparatus, characterized by the following steps:

   a) providing of at least one pre-fabricated base component (14) on which bristle tufts (16) are attached, and which forms a portion of the final brush, wherein a separate support layer (30) is applied on the rear of the base component (14), or at least one pre-fabricated base component (14) which is formed by overmoulding of several bristle tufts (16) containing bristle ends which have been fused together beforehand,

   b) supplying and positioning of the base component (14) containing bristles to or in an injection moulding tool, wherein each base component (14) abuts in a cavity (46) of one half of a mould of the injection moulding tool with the edge thereof on the edge (50) of a respective opening (48) extending from the associated cavity (46) and the bristle tufts (16) project into the opening, and

   c) overmoulding of a bristle portion on the base component on the rear side.
2. The method according to claim 1, characterized in that the base components are retrieved from an inventory of base components comprising bristles and are supplied to the injection moulding tool.
3. The method according to claim 1 or 2, characterized in that no support means in the opening portion are provided to the base components during moulding.
4. The method according to claim 1 or 2, characterized in that supporting protrusions in the opening between bristles having a point or line shape urge against the base component in order to support it during injection moulding.
5. The method according to one of the preceding claims, characterized in that in a bristling machine, bristle tufts are inserted in receiving openings of the pre-fabricated base component and that the bristle tufts are then attached to the rear of the base component without firmly fastening, in particular by melting of the bristles, gluing or overmoulding, wherein the base components located on perforated plates of the bristling machine will be bristled, wherein the perforated plates comprise a perforated pattern corresponding to the perforated pattern of the base components.
6. The method according to claim 5, characterized in that after bristling and fastening the bristle tufts on the rear of the base component, the support layer is applied over a surface area, in particular by injection moulding, wherein, in particular, at most an edge portion of the base component is not covered by the supporting layer.
7. The method according to claim 5 or 6, characterized in that the application of the support layer is performed external to the bristling machine and after or before removing the base components containing bristles from the perforated plates.
8. The method according to one of the preceding claims, characterized in that an insertion tool is provided which compresses the bristles before or during insertion of the base component into the injection moulding tool in order to insert them into the opening of the half of the mold.
9. The method according to one of the preceding claims, characterized in that the bristle tufts are inserted in a perforated plate comprising the perforated pattern of the brush to be produced, and the bristle of the tufts are fused on the rear and then, while still being located in the perforated plate, are injection moulded by forming the base component, wherein the base component containing the bristles is removed from the perforated plate before injection moulding of the bristle body to the base component.
10. An apparatus for producing brushes comprising a method according to one of the preceding claims, characterized by an injection moulding tool containing one half of the mould having at least one cavity (46) for accommodating a base component (14) containing bristles, wherein the cavity (46) comprises an opening (48) for accommodating a plurality, in particular all, bristle tufts and a supporting edge surrounding an opening (48) for abutment and support of the base component (14).
11. The apparatus according to claim 10, characterized in that a plurality of cavities is provided in the half of the mould.
12. The apparatus according to claims 10 or 11, characterized in that the half of the mould is configured with the at least one cavity composed of several parts and comprises a first and a second moulding, where both comprise portions of the at least one cavity which merge into one another, and wherein the first moulding is capable of being separated from the second and is adapted as transport element for the at least one base component.
13. The apparatus according to one of claims 10 to 12, characterized by a bristling machine, wherein the perforated plates and the base components are coupled to one another, wherein a separating station is provided upstream of the injection moulding tool, in which the base components containing bristles are separated from its associated perforated plates.
14. The apparatus according to one of claims 10 to 13, characterized by a coating tool which is arranged between the bristling machine and the injection moulding tool and which applies a support layer on the rear of the base component containing bristles.

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