Device for transferring a material in the form of a film applied to a carrier strip onto a substrate

Information

  • Patent Grant
  • 6792664
  • Patent Number
    6,792,664
  • Date Filed
    Friday, November 15, 2002
    21 years ago
  • Date Issued
    Tuesday, September 21, 2004
    19 years ago
Abstract
A device for transferring a film from a carrier strip onto a substrate such as a sheet of writing or drawing paper comprises a housing in which a supply reel and an empty reel are arranged. The film-coated carrier strip is guided over an applicator foot which is looped around by the carrier strip with a clip-type slide element of a friction-reducing material secured to the applicator foot. The applicator foot comprises a pivotally hinged extension arm having an end in the end portion for receiving a profile member for the slide element.
Description




BACKGROUND OF INVENTION




The invention relates to a device for transferring a material in the form of a film applied to a carrier strip onto a substrate, such as a sheet of writing or drawing paper, comprising a housing in which a supply reel for the film-coated carrier strip and an empty reel for receiving the de-coated carrier strip are arranged, wherein the film-coated carrier strip is guided over an applicator foot provided at least in the region which is looped around by the carrier strip with a clip-type slide element of a friction-reducing material secured to the applicator foot.




Hand devices of that kind for transferring a film (for example, adhesive strip, concealing substance, marking ink, etc.) are known. In that case, in order to achieve a smooth motion and good capability of transfer of the film onto the substrate various embodiments for the shapes of the applicator foot are known. Thus, the applicator foot can be equipped with, for example, an applicator roller which preferably has a rubber-elastic running surface. However, as the external diameter of a functionally effective applicator roller cannot be kept as small as desired, because a good adaptation to the substrate requires a minimum thickness for the elastic running ring and the rotational mobility presupposes a sufficient difference between axle stub and external diameter, such an applicator roller has disadvantages. Accordingly, in most solutions the applicator foot usually has an applicator strip which has advantages relative to an applicator roller, as a sharper angling of the carrier strip is possible in the transfer phase, whereby the torn-off piece has less tendency to formation of a wavy edge after completion of the transfer. Thereagainst it is disadvantageous relative to the applicator roller solution that in the case of the applicator strip the carrier strip is guided thereover with a friction couple which, in dependence on the respective carrier strip quality, can lead to undesired heavygoing.




In principle, synthetic materials which have a good sliding property are known, for example polytetrafluorethylenes (PTFE), but which are higher in cost by a multiple than the standard materials usually used for the components of a device of the kind in question.




Accordingly, the use of an applicator foot of polytetrafluorethylene is excluded on cost grounds.




As polytetrafluorethylene is not a true thermoplastic, a loading of the region, which is effective with respect to guidance, of the applicator foot by this high-quality material in a multi-component injection-moulding process or a subsequent injection-moulding process has to be excluded. A conceivable solution, such as gluing the applicator strip by a self-adhesive foil coated with fluoro synthetic material, has in fact been attempted already, but from the viewpoint of production engineering is unsuitable for mass-produced articles.




A device of the category in question is known from U.S. Pat. No. 5,430,904. In this device the applicator foot is provided in the region which is looped around by the carrier strip with a slide element made of a friction-reducing, rubber-elastic material and fastened to the applicator foot. This slide element is to serve the purpose of achieving faultless transfer of the film onto the substrate. However, it has proved that the smooth motion of the device and the transfer of the film to the substrate is still capable of improvement.




SUMMARY OF THE INVENTION




It is accordingly the object of the invention to so improve a device according to the category that the smooth motion of the device and faultless transfer of the film onto the substrate are guaranteed in return for smallest possible use of material and with particular consideration of economic capability of manufacture and possibility of assembly.




In accordance with the invention this object is met in the case of a device of the kind denoted in the introduction in that the applicator foot comprises a pivotably hinged extension arm having at the end a receiving profile member (end portion) for the slide element.




On the one hand, due to this construction there is achieved, within certain limits, a more flexible articulation of the applicator strip with the slide element at the applicator foot, whereby a better transfer of the film is achieved even to a not completely flat substrate. On the other hand, the clip-type slide element can be mechanically pushed in simple manner onto the extension arm in the pivoted-out position thereof after a spreading process and can be securely fastened to the applicator foot by pivoting in and locking of the arm.




The slide element itself can be produced from, for example, a polytetrafluorethylene tube as a semi-finished product of the smallest dimensions (for example, with an external diameter of 1 to 1.2 millimetres and 0.2 to 0.3 millimetres wall thickness), in that it is cut off to the desired length, slit in longitudinal direction and then spread apart and pushed onto the applicator foot. This can be carried out automatically in simple manner.




In an advantageous embodiment it is provided that the extension arm is securable to the applicator foot in the pivoted-in position by means of a detent connection. After the automatic pushing on of the clip-type slide element the extension arm can then be mechanically pivoted in and then automatically locked to the applicator foot in the pivoted-in position. Moreover, it is, with advantage, provided that abutment steps for securing against twisting and recesses for securing against longitudinal displacement of the clip-type slide element are provided at the applicator foot and/or extension arm.




In order to further facilitate handling of the device it is proposed that the extension arm is provided with longitudinally oriented ribs. These ribs serve, preferably in conjunction with selection of an elastic material—for example, a polyolefin—for the extension arm, for ensuring contact between the applicator foot and possible unevennesses of the substrate plane. As the slide element is similarly elastic, it is thus achieved that even in the case of a non-planar substrate the entire transfer width is acted on by pressure and, in similar manner to an elastic roller, formation of bubbles is prevented.




With particular advantage it is proposed in that case that the ribs rise in wedge-shaped manner starting from the slide element and each have a rear wall which in the pivoted-in position of the extension arm bears against a respective abutment of a cross-member of the applicator foot. In this manner it is possible to bias the ribs in a specific way in the pivoted-in position of the extension arm so as to ensure a bubble-free transfer of the film to the substrate in the case of a non-planar substrate.




In that case it is proposed with particular advantage that the prism-shaped abutments are so constructed that they together form an approximately arcuate support profile for the rear walls of the wedge-shaped ribs. It is thus achieved that the ribs are biased to increasingly greater extent towards the middle of the extension arm and in consequence thereof the slide element describes a spherical course relative to the substrate plane, so that even in the case of a non-planar substrate a sufficient application pressure for a bubble-free transfer is achieved over the entire transfer width.




In order to be able to carry out production of the device in particularly simple manner, i.e. automatically, there is also proposed in accordance with the invention a method for production of the device in which a supply reel with a film-coated carrier strip and an empty reel are inserted into the housing of the device, wherein the method is distinguished by the fact that for formation of the clip-type slide element a tube section of friction-reducing material is located and held, is slit in longitudinal direction and is pushed, while being spread apart, onto the applicator foot or the extension arm.




In that case, for example, a polytetrafluorethylene tube can be fed as a semi-finished product of smallest dimensions, for example with an external diameter of 1 to 1.2 millimetres and a wall thickness of 0.2 to 0.3 millimetres, to an automatic machine, cut to length there, slit mechanically or by another cutting technique, such as laser or water jet cutting, in longitudinal direction and subsequently spread apart by means of a conical holding mandrel to the required assembly profile, whereupon the clip-type slide element is then laterally stripped off onto the applicator foot or the extension arm of the applicator foot.




For carrying out this above-described process there is provided a device which is distinguished by a gripper-like holding device for the tube section, a conical retaining mandrel and a cutting device.











THE DRAWINGS




The invention is hereinafter described in more detail by way of example with reference to the drawing, in which:





FIG. 1

is a perspective illustration of an applicator foot of a device according to the state of the art,





FIG. 2

is a side view partly in section of the applicator foot of a device according to the invention, without slide element,





FIG. 2



a


is a section of the slide element for the device according to

FIG. 2

,





FIG. 3

is the front view of the applicator foot,





FIG. 4

is a side view partly in section of the applicator foot according to

FIG. 2

, with pivoted-in extension arm,





FIG. 5

is a front view of

FIG. 4

,





FIG. 6

is a perspective illustration of the applicator foot,





FIG. 6



a


shows, in the same illustration as in

FIG. 6

, a particularly preferred modified form of embodiment of the applicator foot,





FIG. 6



b


shows the applicator foot according to

FIG. 6



a


in plan view,





FIGS. 7



a


to


7




d


show, partly in section and in simplified illustration, a device for production of the device according to the invention,





FIG. 8

is a perspective illustration, in simplified representation, of the device according to

FIGS. 7



a


to


7




d


and





FIGS. 9 and 9



a


again show the aforesaid device.











DETAILED DESCRIPTION




A device according to the category in question, and belonging to the state of the art, for transferring a material in the form of a film applied to a carrier strip onto a substrate is illustrated in

FIG. 1

, although only the part significant for the invention, namely an applicator foot which is denoted generally by


1


. This applicator foot


1


is equipped with an applicator strip


2


, around which a coated carrier strip


3


, coming from a supply reel, which is not illustrated, of the device is guided. After the transfer of the coating


4


onto a substrate it is passed on as an empty strip


5


to a winding-up reel, which is not illustrated. It has emerged that such an applicator foot


1


is not satisfactory with respect to easy motion of the device and faultless transfer of the film onto the substrate.




According to the invention another design of the applicator foot is therefore provided, this being illustrated in

FIG. 2

et seq.




An applicator foot according to the invention of a device in accordance with the invention is denoted generally by


6


in the figures. This applicator foot


6


comprises strip guide ears


7


between which the carrier strip is guided. The applicator foot


6


is provided with an extension arm


9


pivotably hinged to the applicator foot


6


by way of a film hinge


8


. This extension arm


9


is formed at its end as a receiving profile member (end portion


10


) for a clip-type slide element


15


. Grooves


13


are cut out of the applicator foot


6


and serve the purpose of achieving a detent latching of the extension arm


9


to the applicator foot


6


in the pivoted-in position of the extension arm


9


, for which purpose detent dogs


12


are provided on the extension arm


9


at both outer sides.




As evident from

FIG. 3

, the extension arm


9


comprises ribs


11


which are, for preference, longitudinally oriented. These ribs


11


serve, in conjunction with a selection of an elastic material, for example polyolefin, to ensure contact between the applicator strip (end portion


10


) and possible unevennesses of the substrate plane. As the clip-type slide element


15


of polytetrafluorethylene is similarly elastic, it is thereby achieved that even in the case of a non-planar substrate the entire transfer width of the strip is subjected to pressure and, similarly to an elastic roller, formation of bubbles is reliably prevented so that a smooth coating onto the substrate takes place.





FIGS. 4 and 5

show the extension arm


9


in pivoted-in and locked position. In that case the film hinge


8


is pivoted through about 90°. The clip-type slide element


15


placed on the end portion


10


of the extension arm


9


is additionally fastened in the manner that abutment steps


16


and


17


are provided at the applicator foot


6


or extension arm


9


, whereby the slide element


15


is secured against rotation. It is achieved through contact of the extension arm


9


with a cross-member


18


of the applicator foot


6


that the free end portion


10


of the extension arm


9


can flexibly spring out in its entirety.




The applicator foot


6


with detent dogs


12


notched in the grooves


13


and correspondingly fastened slide element


15


is recognisable in front view from FIG.


5


. Through abutments


19


at the applicator foot


6


it is achieved that, in the case of possible excessive applied pressure by inappropriate handling of the device, the applicator strip formed by the slide element


15


reaches a final end abutment which is so dimensioned that the slide element


15


always protrudes by a few tenths of a millimetre beyond the profile of the strip guide ears


7


, so that the transfer function is remains secured. Moreover, it is recognisable that the ends


20


of the clip-type slide element


15


are advantageously arranged to be recessed in recesses


21


of the strip guide ears


7


, whereby it is ensured that the carrier strip is kept away from the ends


20


possibly compressed by the cutting to length of the tube from which the slide element


15


is preferably produced.




In

FIG. 6

the entire applicator foot


6


is illustrated again in functional position, i.e. with pivoted-in and locked extension arm


9


, and in particular in the end position of the clip-type slide element


15


with securing against rotation and longitudinal displacement.




An alternative embodiment is illustrated in

FIGS. 6



a


and


6




b


, in which the ribs are differently shaped, these ribs being denoted by


11


′. The ribs


11


′ rise in rearward direction in wedge shape starting from the slide element


15


and each have a rear wall


11





a


, which in the pivoted-in position of the extension arm


9


bears against a respective abutment


31


at the cross-member


18


of the applicator foot


16


. In that case the prismatic abutments


31


are constructed so that they together form an approximately arcuate contact profile K—K for the rear walls


11





a


of the wedge-shaped ribs


11


′.




It is achieved by this design that the ribs


11


′ are biased to increasingly greater extent towards the centre of the extension arm


9


and in consequence thereof the slide element


15


describes a spherical course Z—Z relative to the substrate plane and thus, even in the case of a non-planar substrate, a sufficient application pressure for a bubble-free transfer is attained over the entire transfer width.




A device for production of the clip-type slide element


15


is shown in strongly simplified representation in

FIGS. 7



a


to


7




d


. This device comprises, first of all, a gripper


22


to which a polytetrafluorethylene tube section


23


is fed. This tube section in that case comes into contact with an annular step


30


of the gripper


22


. A substantially conical retaining mandrel


24


with a front-mounted knife


25


is moved downwardly within the gripper


22


and starts cutting, wherein guide chamfers


26


of the gripper


22


serve as an aid at the junction (

FIG. 7



a


).




On further downward movement of the retaining mandrel


24


(

FIG. 7



b


), the now cut-open tube section


23


′ is continuously spread apart by the conicity of the retaining mandrel


24


and the gripper


22


is opened, wherein the abutments of the annular step


30


travel therewith and thus prevent the tube section


23


′ from giving away.




In the illustration according to

FIG. 7



c


the retaining mandrel


24


has reached its end position. The tube section


23


′ has now received the cross-sectional profile of the end piece


10


of the extension arm


9


.




As evident from

FIG. 7



d


, the special profiling of the retaining mandrel


24


in its upper end region ensures that the cut edges of the clip-type slide element


15


are held exactly in position by abutment steps


27


at the upper region of the retaining mandrel


24


.




The working sequence according to

FIGS. 7



a


to


7




c


is reproduced again in perspective illustration in

FIG. 8

by reference to a symbolically reproduced device, from the tube section


23


up to the shaping, appropriate for mounting, of the processed tube section


23


′ or the clip-type slide element


15


resulting therefrom.




After lowering of the retaining mandrel


24


in the arrow direction A the gripper


22


is opened and the retaining mandrel moved back in direction B, rotated through 180° in the arrow direction C and pivoted in the arrow direction D.




In the position reproduced in

FIG. 9

, the retaining mandrel


24


pivoted in the arrow direction D is in alignment and the clip-type slide element


15


is fed to the end piece


10


of the extension arm


9


of the applicator foot


6


positioned in a holding device


28


.




After lowering of the retaining mandrel


24


in the arrow direction E, the clip-type slide element


15


can now be pushed in accurately fitting manner onto the end piece


10


by means of a stripper


29


moved in the arrow direction F (see the more exact illustration in

FIG. 9



a


). Not illustrated is the pivoting of the extension arm


9


into the end position of the finished part, as shown in FIG.


4


.




The invention is obviously not restricted to the illustrated embodiments. Further refinements are possible without departing from the basic concept. Thus, in particular, the device shown in

FIG. 7

et seq can also be realised in other ways and suchlike.



Claims
  • 1. An arrangement for forming a dispensing device for transferring a film from a carrier strip onto a substrate wherein the device includes an applicator foot having an end piece, said arrangement comprising a structure for forming a clip-on slide element from a tube section, said structure including a gripping holding device for holding the tube section, a conical retaining mandrel movably mounted for insertion into the tube section, a cutting device for slitting the tube section, a holder having mounting structure for holding the applicator foot and the end piece of the dispensing device, and said mounting structure which holds the end piece being in line with the path of movement of said mandrel whereby the cut tube section is transferred from said mandrel to the end piece of the dispensing device so that the cut tube section becomes the clip-on slide element of the applicator foot.
  • 2. The arrangement of claim 1 wherein said gripping holding device includes an annular step for being contacted by the tube section.
  • 3. The arrangement of claim 2 wherein said gripping holding device includes guide chamfers.
  • 4. The arrangement of claim 3 wherein said cutting device is a front-mounted knife movable downwardly within said gripping holding device.
  • 5. The arrangement of claim 1 wherein said gripping holding device includes guide chamfers.
  • 6. The arrangement of claim 1 wherein said cutting device is a front-mounted knife movable downwardly within said gripping holding device.
  • 7. The arrangement of claim 1 including a stripper movably mounted toward said mandrel for pushing said tube section off said mandrel and onto the end piece.
  • 8. The arrangement of claim 1 combination with the dispensing device, said dispensing device including a housing having a supply reel and an empty reel with the carrier strip guided over said applicator foot, said applicator foot being in the form of a pivotally hinged extension arm having a receiving profile member for said slide element, and said slide element being made of a friction-reducing material.
Priority Claims (2)
Number Date Country Kind
198 37 573 Aug 1998 DE
198 59 269 Dec 1998 DE
CROSS REFERENCE TO RELATED APPLICATION

This application is a division of application Ser. No. 09/763,427, filed Feb. 20, 2001, now U.S. Pat No. 6,481,485 which is a 371 of PCT/EP99/05787 filed on Mar. 2, 2000.

US Referenced Citations (4)
Number Name Date Kind
3715941 Andrews et al. Feb 1973 A
3921482 Osborn Nov 1975 A
4160398 Bichot et al. Jul 1979 A
4957022 Harris Sep 1990 A