The present invention relates to a binding folder.
More specifically, the invention relates to a binding folder that is provided with a spine that is intended to have an edge of a bundle of leaves inserted therein, whereby this spine is provided with two cover sheets that are intended to protect the bundle of leaves.
Such binding folders are already known and enable a bound bundle of leaves or a book to be produced easily and flexibly.
The known binding folders comprise a metal or cardboard spine provided with hotmelt adhesive to which two, often plastic, cover sheets are attached.
Plastic cover sheets have the advantage that they are light and robust, and in most cases are resistant to moisture or water, such as rain for example.
The bundle of leaves can be affixed in the spine by means of the hotmelt adhesive, whereby it is possible that the arms of the spine are then bent towards one another to fit relatively closely against the bundle or even to clamp in the bundle.
Such known binding folders present the disadvantage that the plastic cover sheets are often statically charged, such that when inserting the bundle of leaves, the outermost leaves experience a type of force of attraction as a result of this static electricity that results in the leaf clinging to the plastic cover sheets as it were.
As a result the outermost leaves are not affixed or not well affixed in the spine.
Cover sheets with a smooth or shiny surface in particular are subject to these detrimental effects of static electricity or static charge.
This has the disadvantage that the outermost leaves are not well aligned with the rest of the bundle of leaves. The finished, bound bundle thus has an inferior quality and appearance or ‘look’.
An additional disadvantage is that the outermost leaves are not well affixed in the hotmelt adhesive so that they are not bonded in the spine. This means that these leaves can come loose from the finished and bound bundle.
There are already solutions for such problems.
A first known solution consists of a device that can remove this charge from the surface of the cover sheets.
This is very expensive and very difficult to apply to a finished product.
Moreover, the slightest rubbing on the surface of the plastic cover sheet will charge this surface again. For example, sliding two binding folders over one another or taking a binding folder out of packaging will be sufficient to create static electricity again.
Another known solution consists of making the surface of the cover sheet rougher with micro-irregularities. This will ensure that air can always remain between the outermost leaf of the bundle and the cover sheet.
As a result of this air layer the force of attraction or the ‘adhesive force’ between the outermost leaf and the cover sheet is reduced, but not completely absent.
An additional disadvantage of this is that the appearance of the cover sheet is changed and that a previously shiny cover sheet becomes matt due to these irregularities and that, due to these irregularities, a previously transparent cover sheet is no longer transparent, which is desirable for most end users.
The purpose of the present invention is to provide a solution to at least one of the aforementioned and other disadvantages.
To this end the invention concerns a binding folder for binding a bundle of leaves, whereby this binding folder essentially comprises a spine for enclosing an edge of the bundle of leaves and two cover sheets attached to the spine, at least one of which is made of a synthetic material, whereby at least one cover sheet is provided with a top sheet against the side of the cover sheet oriented towards the inside of the binding folder, whereby this top sheet is attached to the cover sheet and/or spine in a removable way.
The side of the cover sheet oriented towards the inside of the binding folder means the side of the cover sheet that will be oriented towards the bundle of leaves when the bundle of leaves is bound by means of the binding folder.
An advantage is that the top sheet that is affixed against the plastic cover sheet will ensure that the outermost leaves of the bundle are not held back by the static charge of the cover sheet.
In order to obtain this effect the top sheet is made of a material that is not statically charged or scarcely statically charged, or very difficult to statically charge, such as single-layer or multilayer paper, cardboard, a synthetic material, or any material that is barely statically charged due to rubbing.
The top sheet will act as a type of intermediate screen between the strongly electrostatically charged or otherwise cover sheet and the outermost leaves of the bundle, so that they cannot ‘cling’ together.
Due to the intermediate screen or top sheet, the outermost leaf of the bundle together with the other leaves of the bundle can be affixed in the spine.
As a result all leaves of the bound bundle are nicely aligned so that a nice and perfectly bound bundle of leaves can be obtained.
Moreover, all leaves will be affixed well in the spine and in any hotmelt adhesive, so that a good binding of all leaves can be obtained.
Because the top sheet is attached in a removable way to the cover sheet and/or the spine, after binding the bundle it can be removed so that it is no longer visible in the finished and bound bundle, possibly save for a small remaining piece.
This is also a cheap and effective solution for the detrimental effects of the static charge.
Moreover, it will be possible to use transparent cover sheets with a smooth surface, i.e. without micro-irregularities.
It is possible that both cover sheets are made of a synthetic material, but it is also possible that one of the two cover sheets is made of another material, such as paper or cardboard for example.
Preferably the top sheet is attached to the binding folder by means of an adhesive that is provided on the top sheet.
This has the advantage that it is easy to realise, for example by bonding such a top sheet to the cover sheet with an adhesive after production of the binding folder.
According to a preferred characteristic of the invention the top sheet is approximately just as large as the cover sheet.
This has the advantage that the outermost leaves of the bundle will have optimum protection against the effects of any static charge on the cover sheet.
If both cover sheets are made of a synthetic material or another material that is sensitive to electrostatic charge, preferably each cover sheet is provided with a top sheet against the side of the cover sheet concerned oriented towards the inside of the binding folder, whereby this top sheet is attached in a removable way to the cover sheet concerned and/or the spine.
In this way the outermost leaves of both sides of the bundle are protected against the static charge on the plastic cover sheets.
With the intention of better showing the characteristics of the invention, a few preferred embodiments of a binding folder according to the invention are described hereinafter by way of an example, without any limiting nature, with reference to the accompanying drawings, wherein:
The binding folder 1 according to the invention shown in
In this case, but not necessarily, the spine 2 is a U-shaped or V-shaped profile with a base 7 and two arms 8.
As shown in
This adhesive 9 is a hotmelt adhesive for example that will melt due to the heating of the base 7 of the spine 2.
According to the invention at least one cover sheet 5 or both cover sheets are made of a synthetic material. In this case both cover sheets 5 are made of a synthetic material and one cover sheet 5 is provided with a smooth and shiny surface. Such a type of cover sheet 5 is preferred by most end users because it has very good aesthetic properties. Moreover, a smooth cover sheet 5 can also be made transparent, in contrast to a rough cover sheet 5.
The other cover sheet 5 can be provided with a matt and translucent surface, and is translucent but not transparent.
According to the invention at least one cover sheet 5, in this case the smooth and shiny cover sheet 5, is provided with a top sheet 10, which in this case is made of paper or an antistatic synthetic material, in other words a synthetic material on which or in which no or practically no static electric charge can accumulate.
An example of an antistatic synthetic material is an antistatic polyethylene film (LDPE film) that moreover provides the advantage of being scratch-free, and consequently the cover sheet 5 on which the top sheet 10 is attached is protected against scratches.
Such an antistatic film can also be made transparent so that in the case of a transparent cover sheet 5 the transparency is preserved after affixing the cover sheet 10, so that it is immediately clear to the user when choosing a new binding folder 1 that he can select a binding folder 1 with transparent cover sheet 5 without first having to consult the packaging thereon.
The top sheet 10 is affixed against the side 11 of the cover sheet 5 oriented towards the inside of the binding folder 1, i.e. against the side 11 of the cover sheet 5 that will be oriented towards the bound bundle 4 of leaves. This side 11 can be considered as the ‘inside’ of the cover sheet 5.
In this case, the top sheet 10 is somewhat smaller than the dimensions of the cover sheet 5.
The cover sheet 10 is attached to the cover sheet 5 in a removable way.
In the example shown, by means of an adhesive that is provided in the form of a strip of adhesive 12 on the top sheet 10, as can be seen in
In this case the strip of adhesive 12 is a continuous strip 12, but can also be a discontinuous strip 12 that is made up of a number of successive partial strips of adhesive, with zones in between that are free of adhesive.
The adhesive used for the strip 12 is preferably a glue or cold glue that can be self-adhesive or otherwise, and which will enable the top sheet 10 with the adhesive to be removed from the binding folder 1.
The strip of adhesive 12 is situated on an edge 13a of the top sheet 10, whereby this edge 13a extends parallel to the spine 2. This is schematically shown in
As can be seen, this edge 13a of the top sheet 10, where the strip of adhesive 12 is located, is oriented away from the spine 2.
The other edge 13b of the top sheet 10 that extends parallel to the spine 2 and is located closer to the spine 2, is not provided with a strip of adhesive and can in principle be lifted up. But, due to the possible presence of static electricity the top sheet 10 will ‘cling’ to the cover sheet 5 due to the force of attraction of the static charge or by adhesion or the vacuum between the cover sheet 5 and the top sheet 10.
It is clear that although the strip of adhesive 12 is parallel to the spine 2, it can also be affixed obliquely opposite the spine 2. This means that the strip of adhesive 12 does not extend parallel to the spine 2.
The strip of adhesive 12 can be affixed at the location of the edge 13a or 13b, or at any position between these two edges 13a or 13b or over the entire surface between 13a and 13b.
In order to bind a bundle of leaves 4 in a binding folder 1, as shown in
A bundle of leaves 4 is affixed in the spine 2 of the binding folder 1, for example by holding the spine 2 with one hand and introducing the bundle of leaves 4 into the spine 2 with the other hand until the aforementioned edge 3 is against the base 7 covered with a layer of adhesive 9. This is shown in
Because of the top sheet 10 there will be no force of attraction between the outermost leaves 14 of the bundle 4 and the cover sheets 5 so that all leaves of the bundle 14 will go into the hotmelt adhesive 9.
Because the strip of adhesive 12 is at the edge 13a of the top sheet 10 that is oriented away from the spine 2 or over the entire surface of the cover sheet 10, the outermost leaves 14 of the bundle 4 will not undesirably and accidentally end up between the top sheet 10 and the cover sheet 5, because the strip of adhesive 12 will keep the top sheet 10 against the cover sheet 5.
Then the layer of hotmelt adhesive 9 in the spine 2 will be heated so that it becomes liquid.
This can be done by placing the binding folder 1 with the spine 2 on a hot plate, so that the layer of hotmelt adhesive 9 will melt under the influence of the heat.
After solidification of the hotmelt adhesive 9 in the spine 2, the bundle of leaves 4 will be bound in the binding folder 1.
If desired, the arms 8 of the spine 2 can also be folded or pressed in to clamp the bundle 4 between the arms 8 of the spine 2.
Then the top sheet 10 can be removed by lifting up the aforementioned edge 13b of the top sheet 10 that is not provided with a strip of adhesive 12 and thereby detaching the strip of adhesive 12 from the cover sheet 5.
Because use is made of a self-adhesive glue, this top sheet 10 can easily be removed without leaving adhesive residues on the cover sheet 5.
The user can of course choose not to remove the top sheet so that when leafing through the folder with a bound bundle 4, the outermost leaves 14 of the bundle do not continue to cling to the cover sheets 5.
Furthermore the top sheet 10 is provided with printing 15 on one side. It is not excluded that the other side or both sides of the top sheet 10 are provided with printing 15.
This printing 15 can comprise instructions for example on the use of the binding folder 1 or other information, or promotional or advertising messages, for example.
An advantage of the top sheet 10 that comprises instructions is that this information will not be lost because the top sheet 10 is affixed in the binding folder 1.
The user will always have this ‘memory aid’ available for each binding folder that he uses to bind a bundle of leaves 4, so that a nicely bound bundle 4 can be obtained each time by following the instructions.
In this case the top sheet 10 is provided with a ‘tab’ or protruding lip 16.
This has the advantage that the top sheet 10 can be easily removed, even if it is attracted to the cover sheet 5 by the static charge of the cover sheet 5, by taking hold of this protruding section 16.
The top sheet 10 is affixed against the cover sheet 5 such that the tear-off strip 17 is at least partially in the spine 2, as can be clearly seen in
In other words the strip of adhesive 12 is against an arm 8 of the spine 2. In other words, the top sheet 10 is attached to the spine 2 of the binding folder 1 and not to a cover sheet 5, such as in the previous embodiments.
It is of course not excluded that the tear-off strip 17 is completely in the spine 1.
Preferably the width of the tear-off strip 17 is equal or approximately equal to the depth of the spine 2. This has the advantage that the strip 17 is completely in the spine 2, but that the protective strip 10 can still easily be torn away along the perforated line 18 because it is situated at the location of the free end of the arms 8.
After affixing a bundle of leaves 4 in the binding folder 1 as shown in
As the strip 17 is as good as completely in the spine 2, it will almost be invisible.
Although in the example of
The strips of adhesive 12 are both on an edge 13a of the cover sheet 10 oriented away from the spine.
Although in the examples shown above the adhesive is applied in the form of a continuous, uninterrupted strip of adhesive 12 on the top sheet 10, it is not excluded that the adhesive is applied over the entire surface of the top sheet 10 or in the form of a number of local points. For example, the adhesive can be applied on the surface of the top sheet 10 in the form of one, two, three or more drops of adhesive or in the form of a discontinuous strip of adhesive that is made up of a number of consecutive partial strips of adhesive with zones in between that are free of adhesive. It is also not excluded that a number of continuous or discontinuous strips of adhesive 12 are applied.
It is also possible that the adhesive 12 is applied in a thin layer over an entire side of the top sheet 10. In this case, for example, for the cover sheet 10 use can be made of a multilayer film 22 cut to size with an antistatic outer layer 23, for example antistatic polyethylene, and a thin layer of adhesive 24 as shown in
As described above the strip of adhesive 12 can be applied in parallel or otherwise to the spine 2 at each location between the edge 13a and the edge 13b of the top sheet 10.
In the drawing shown this free edge 20 is parallel to the spine, but this is not necessarily the case.
Hereby the folded strip 19 is preferably affixed on the outside of the cover sheet 5, as can be seen in
Such an embodiment has the advantage that no adhesive is required. The top sheet 10 is attracted to the cover sheet 5 due to the static charge of the cover sheet 5, so that it remains in place.
The spine 2 of the binding folder 1 can be made of metal that is clad with paper or fabric or otherwise, but can also be made of cardboard or a synthetic material.
In this case, but not necessarily, this first cover sheet 5 and the spine 2 are made of one continuous piece of cardboard. This can clearly be seen in
The second cover sheet 5 is made of a synthetic material. This can be a matt or smooth and shiny synthetic material, transparent or otherwise.
This second cover sheet 5 is provided with a top sheet 10, analogous to
The binding folder 1 is provided with a top sheet 10 that is affixed to one of the cover sheets 5.
In this case adhesive is provided on the top sheet 10 in the form of two drops of adhesive 21, on an edge 13b of the top sheet 10 that extends parallel to the spine 2, whereby this edge 13b is oriented towards the spine 2.
The drops of adhesive 21 are situated at the location of the corners of the top sheet 10, but this is not necessarily the case.
Moreover, there can only be one drop or three or more drops of adhesive 21.
The drops of adhesive 21 ensure an attachment of the cover sheet 10 at a number of local points.
In this case the top sheet 10 is affixed against the cover sheet 5 such that the aforementioned drops of adhesive 21 are at the location of the spine 2, more specifically at an upright arm 8 of the spine 2.
The aforementioned edge 13 is at some distance A from the base 7 of the spine 2.
This distance A is preferably between three and seven millimetres or even better between five and seven millimetres.
As a result this can prevent the top sheet 10 from also being bound in the spine 2 by means of the hotmelt adhesive 9, when a bundle 4 is bound in the spine 2.
The difference to the embodiment of
In this case the cover sheet 10 will be completely removed after the bundle 4 is affixed in the binding folder 1. Because only two drops of adhesive 21 are used, it will be possible to completely remove the top sheet 10 from the binding folder 1.
An advantage is that the tear-off strip 17 is not left behind in the spine 2, which can be unattractive if the tearing is not done neatly.
Moreover, this has the advantage that if adhesive is left behind on the cover sheet 5, it will not be visible because the adhesive left behind will be at a location that is hidden from view after binding a bundle 4.
Although in the example of
It is also possible to apply the strip of adhesive 12 in the centre over a length of 10 cm for example in discontinuous or continuous form.
The present invention is by no means limited to the embodiments described as an example and shown in the drawings, but a binding folder according to the invention can be realised in all kinds of forms and dimensions, without departing from the scope of the invention.
Number | Date | Country | Kind |
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2015/5351 | Jun 2015 | BE | national |
2015/5581 | Sep 2015 | BE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2016/000319 | 3/17/2016 | WO | 00 |