This application is the 35 U.S.C. §371 national stage of PCT application PCT/IB2011/051664, filed Apr. 18, 2011, which claims priority to and the benefit of European Application No. 10425201.0, filed Jun. 16, 2010, both of which are hereby incorporated by reference in their entirety.
The present patent relates to equipment for the production of bags or shopping bags in paper or other materials, and specifically relates to a carousel handle-forming machine to shape and attach the handles to said bags.
Machinery and systems for the production of paper bags or carrier bags comprising various stations and equipment for the shaping and production of the bag, obtained by cutting and folding a strip of paper or other material, and one or more devices, commonly known as handle-forming machines, for shaping and attaching the handles, are known of.
Various types of handle-forming machines are known of which envisage operations of unwinding one or more paper and/or cord strips, from which each handle is made, of folding and cutting said strip to size to form each handle, and applying the handle to the bag or in continuum, to the roll of paper which the bag will be made from.
The handle-forming machines of the prior art have many drawbacks and disadvantages.
In particular, the handle-forming machines applying handles in continuum to the roll of paper which the bags will subsequently be made from are extremely complicated from a mechanical point of view and, in addition, given their functioning, are subject to jamming and accidental interruption of the manufacturing process.
In fact, as the production speed increases, the risk of a single handle not being perfectly attached to the roll of paper, with the risk of the detached or partially detached handle getting jammed in the mechanisms of the handle-forming or bagging machine and causing dangerous obstruction, increases exponentially.
Such obstructions may not only lead to prolonged downtime of the machine but also to damage of one or more parts of the machine itself.
Currently the production speed of paper or similar bags with a flat bottom is approximately 1000 pieces per minute, while the production speed of paper or similar bags with a square bottom is slower, about 150 pieces a minute.
Such production speed is not supported however by the known handle-forming machines, which need to keep the speed of shaping and attaching the handles to lower levels so as to prevent such risks of jamming.
Handle-forming machines for making so-called strap handles, that is each comprising a segment of paper or similar, folded once or more in a longitudinal direction, to form a linear strap are also known of. The end sections are then folded in relation to the central section to form a substantially U-shaped strap. Said strap handles are attached to the roll of paper after applying glue to the sides folded into a U and to a transversal reinforcement patch of said sides folded into a U.
To make the strap type handles, the handle-forming machine is fed with one or more strips of paper, which are usually folded once or more, as many as four times in a longitudinal direction, to make a more rigid strip.
The continuous strip is cut to size and grasped by rotating drums with grippers which cause folding of the strap. The strap is then rotated and attached to the preformed bag or to the roll of paper which the bag will be subsequently made from, by a plurality of drums.
To prevent the strap from shifting or moving away from the surface of the drum or drive belt during the exchange between various drums, suction devices are used inside the drums or under the belts to keep said straps perfectly adherent to the surface of the drum or belt.
In addition, on account of the presence of said sliding belts, the speed of the handle-forming machines cannot be increased beyond determined limits, which would entail excessive mechanical stress on the belts themselves, with the risk of breakage.
In the known handle-forming machines the rollers must work in perfect synchrony, with the maximum precision, to limit the amount of jamming, which is however inevitable.
To overcome the aforementioned drawbacks a new type of carousel handle-forming machine has been designed and produced for the continuous application of strap handles to continuous rolls of paper for the subsequent production of paper or similar bags and carrier bags.
The main purpose of the present invention is to increase the hourly production of bags and carrier bags, maximising the speed of the shaping and attaching phase of the strap handles.
Another purpose of the present invention is to eliminate the risk of jamming and shifting of the straps from the correct position during the shaping phases, since each strap is kept gripped by a single device or cradle, throughout the folding and positioning phases, without having to pass from one device to another as happens with the known handle-forming machines.
Another purpose of the present invention is to ensure continuity in the shaping and attachment phase of the handles, without having to invert the direction of advancement of the handles in a discontinuous manner.
Another purpose of the present invention is to avoid the use of rollers and drive belts for the straps as well as of suction devices, thereby almost completely eliminating the risk of jamming connected with the use of the aforesaid devices.
These and other purposes are achieved by a handle-forming machine according to claim 1.
The characteristics of the handle-forming machine according to the present invention will be clearer from the following description made by way of a non-limiting example with reference to the attached drawings, wherein:
In the aforesaid figures, reference numeral (10) globally denotes a handle-forming machine for shaping and attaching strap handles (M′) to bags or carrier bags, in paper or other material and/or to continuous rolls of paper (N) for making bags or carrier bags, in paper or other material, said strap handles (M′) being formed by substantially folding into a U shape at least one strip or strap (M), in paper or other material.
The handle-forming machine (10) comprises at least one carousel (G) rotating around a main shaft (Gx), said carousel (G) in turn comprising a plurality of arms (B) substantially radial to the main shaft (Gx), and one or more cradles (C) or devices for gripping and folding one or more straps (M), the cradles (C) being distributed radially on the carousel (G). Preferably, each cradle (C) is mounted at the end of one of the arms (B).
Each of the cradles (C) rotates jointly with the corresponding arm (B) to which it is attached, specifically the cradle (C) rotates around the main shaft (Gx) at least from one strap/s (M) feed station (1) to one station (4) folding each strap (M′) into a U shape and to one loading station (5) of the folded strap (M′), for attachment to the bag or continuous roll of paper (N) which the bag will be made from.
Each of the cradles (C) swivels and also rotates around its own axis (Cx) radial to the main shaft (Gx), that is incident and perpendicular to the latter, to rotate the position of the relative strap (M) between the feed (1), folding (4) and loading (6) stations.
During the rotation of the carousel (G), around the main shaft (Gx), and of the cradles (C), each around its own radial axis (Cx), each strap (M) is also substantially folded into a U shape, to form the handle (M′), and is positioned correctly for its final attachment to the continuous roll which the bags will be made from.
According to one embodiment, the handle-forming machine (10) comprises at least two series of cradles (Ca, Cb) and two series of radial arms (Ba, Bb) rotating in a synchronised manner around said axes (Gx, Cx), each of the cradles (Ca) and the relative arm (Ba) of one series being flanked with a relative cradle (Cb) and relative arm (Bb) of the second series.
In other words, the arms (B) rotate around the main shaft (Gx) in a synchronised manner, to remain flanked and parallel in pairs at all times so that the cradles (C) too, and therefore the two straps (M) respectively restrained by each cradle (C), are always kept in corresponding positions during rotation around the main shaft (Gx), to be folded into a U, rotated and then loaded in a synchronised manner and at the same height onto said roll (N) of paper or other material.
The handle-forming machine (10) comprises at least one unwinding and folding station (P) of one pair of continuous strips (P1a, P1b) flanked for the realisation of said straps (M), one for each of the series of cradles (Ca, Cb). In the unwinding and folding station (P) of the roll of paper (N), each of the strips (P1a, P1b) is folded once or more in the longitudinal direction of the strip (P1a, P1b) so as to form continuous folded strips (P2a, P2b) for the realisation of the straps (M). Such folding makes said strips more rigid.
The handle-forming machine (10), as shown in
Each of the cradles (C) in the feed position (1) is positioned so that the strap (M), initially straight and linear is positioned tangentially to the rotary movement of the cradle (C) around the main shaft (Gx) and orthogonally to the main shaft itself.
Each of the cradles (C) therefore rotates around the main shaft (Gx) from the feed position (1) of the strap (M) to a scoring position (3) of the strap (M) along folding lines (M1) (
In the scoring position, the strap (M) is punched or scored with slots, that is folding lines (M1), to facilitate its subsequent folding into the desired form. Such folding is performed with the help of one or more guides (E1, E2) (
Said guides (E1, E2) mounted on the carousel (G) cause the raising and folding of two opposite lateral sections (M3, M4) of the strap (M), so that it is finally substantially bent into a U shape, presenting a linear central side or section (M2) and lateral sections or sides (M3, M4) folded in relation to said central section (M2), and where the folded strap (M′) is placed, in the folding position (4), with the central side (M2) parallel to the main shaft (Gx) of the carousel (G), and the lateral sections (M3, M4) facing opposite the direction of rotation around the main shaft (Gx).
The folded straps (M′) are retained by the relative cradle (C), which comprises a central gripper (C2) retaining the central section (M2) of the folded strap (M′), and two further lateral grippers (C3, C4) which respectively retain said two lateral sections (M3, M4) of the folded strap (M′).
So (
The handle-forming machine (10) comprises at least one loader (F) rotating around at least one axis (Fx1, Fx2) parallel to the main shaft (Gx) of the carousel (G), able to grasp the folded strap (M′) from the loading position (5) (
The loader (F) comprises, in particular, one or more grippers (F1, F2) able to grasp the folded sides (M3, M4) of the strap (M′) from the outside. Preferably, the peripheral rotation speed of the grippers (F1, F2) of the loader (F) is the same as the peripheral rotation speed of the cradles (C) of the carousel (G) at the moment of grasping of the strap (M′) by the grippers (F1,F2). Such rotation speed of the grippers (F1,F2) and of the cradles (C) may, advantageously, be regulated and equalised so as to ensure the synchrony of gripping or grasping of the strap (M′) by the grippers (F1,F2).
To ensure greater precision, the rotation of the loader and/or of the carousel is controlled by one or more motors on relative shafts, preferably of the “brushless”, electronically controlled type.
The handle-forming machine (10) comprises one or more rollers (H, H1) pressing the straps (M′) onto the continuous roll of paper (N), wherein the lateral sections (M3, M4) of the straps (M′) are inserted by the loader (C) between the roll of paper (N) and the rollers (H, H1).
At least the first of said rollers (H1) has a total overall width less than the length of the central side (M2) of the strap (M′), so that the grippers of the loader (F) do not collide with the roller (H1) itself, as shown in
For the attachment of each strap (M′) to the roll of paper (N), the rollers (H,H1) run over the roll of paper (N) and the folded sides (M3,M4) of the straps (M′) are inserted between the roll of paper (N) and the rollers (H,H1). During the attachment phase of the strap (M′) to the associable roll of paper (N) the speed of advancement of the strap (M′) adjusts to the speed of advancement of the roll of paper (N). Such adjustment of the speed of advancement of the strap and of the roll of paper is preferably performed using numerically controlled “brushless” type motors.
The folded sides (M3, M4) of the straps (M′) are then pressed onto the roll of paper (N) which the glue was previously applied to.
In this regard, the handle-forming machine (10) may also comprise one or more devices for applying (L) and drying (O) the glue on the roll of paper (N) in the area where the folded straps (M′) will be applied. According to one embodiment, the handle-forming machine (10) comprises at least one device for cutting (Q1a, Q1b) and attaching (Q2a, Q2b) reinforcement patches (Sa, Sb) of the straps (M′) to the continuous roll of paper (N) after the application of the straps (M′) to the said roll, wherein the reinforcement patches (Sa, Sb) are fed from at least one feed station (S).
As may be seen from the description, the handle-forming machine according to the present invention, makes it possible to resolve the drawbacks and limitations of the prior art.
In fact, the handle-forming machine according to the present invention makes it possible to increase the hourly production of bags and carrier bags, maximising the speed of the shaping and attachment phase of the strap handles. Such hourly production increase does not entail any reduction in reliability of the equipment which proves reliable and free of jamming.
In fact, first of all the straps are gripped by innovative mechanical grippers in place of the conventional systems using vacuums: this way the inevitable jamming caused by vacuum mechanisms is avoided.
Moreover, the gripping of the strap is improved in that it occurs in a parallel not transversal, and continuous manner. The speed of the cradle is equalised to the speed of the tape to be gripped and only after gripping is the strap cut to size. In other words, the preformed strap is only cut after being grasped by the mechanical grippers, thereby preventing any possibility of it falling in the first changeover.
Moreover, the cut tape is retained by said mechanical gripper for the entire handle-forming process, avoiding changeovers with other gripping mechanisms which would add to the risk of dropping said handle.
The synchronism of all the parts of the handle-forming machine, and in particular of the speed of rotation of the grippers and of the cradles, as well as of the speed of rotation of the cradles and the speed of advancement of the roll of paper, is ensured by the use of numerically controlled motors.
The guarantee of synchronism, together with the fact that the handle is always retained by the same gripper without any further exchange, enables a production speed of paper bags double that of the handle-forming machines of the prior art.
Moreover, the carousel according to the present invention makes it possible to incorporate in a single element all the main gripping, cutting and folding operations of the strap to form the handle to apply to the associable bag. The present invention therefore permits, for the same functioning, a considerable reduction in size compared to the devices of the prior art.
A person skilled in the art may make numerous modifications and variations to the handle-forming machines described above so as to satisfy contingent and specific requirements while remaining within the sphere of protection of the invention as defined by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
10425201 | Jun 2010 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB2011/051664 | 4/18/2011 | WO | 00 | 12/11/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/158132 | 12/22/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2529976 | Strandberg | Nov 1950 | A |
3034409 | Finke et al. | May 1962 | A |
3424067 | Blair | Jan 1969 | A |
3439591 | Class | Apr 1969 | A |
3554099 | Rodley | Jan 1971 | A |
3613523 | Wesselmann | Oct 1971 | A |
3660204 | Wesselmann et al. | May 1972 | A |
3706625 | Jones et al. | Dec 1972 | A |
3753824 | Bosse | Aug 1973 | A |
3818810 | Bosse | Jun 1974 | A |
3850724 | Lehmacher | Nov 1974 | A |
5356221 | Achelpohl et al. | Oct 1994 | A |
5382215 | Mattiebe | Jan 1995 | A |
6574940 | Dauder Guardiola | Jun 2003 | B2 |
7322919 | Malini | Jan 2008 | B2 |
20050119101 | Constant | Jun 2005 | A1 |
20100331159 | Chiu et al. | Dec 2010 | A1 |
Number | Date | Country |
---|---|---|
1181035 | Nov 1964 | DE |
2013115 | Mar 1970 | FR |
49-42470 | Apr 1974 | JP |
54-004317 | Mar 1979 | JP |
Entry |
---|
International Search Report and Written Opinion dated Jul. 21, 2011. |
English Translation of Office Action dated Sep. 24, 2014; Japanese patent application No. 2013-514806; 3 pages. |
Number | Date | Country | |
---|---|---|---|
20130203577 A1 | Aug 2013 | US |