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Title:
LINE, METHOD AND PROCESSING STATION FOR FORMING DOUGH DISKS SUCH PIZZA BASES OR THE LIKE
Document Type and Number:
WIPO Patent Application WO/2008/142660
Kind Code:
A2
Abstract:
A line for forming dough disks (P, P', P"), such as for pizza or the like. The line (1) has an input (2) for at least the portions of yeast dough (P, P', P"), a first processing station (3) with a plurality of presses (4, 4', 4") susceptible of interacting with the dough (P, P', P") to obtain a plurality of substantially disk- shaped elements, a second processing station (5) with a plurality of sheeting devices (6, 6', 6") susceptible of interacting with the pressed disks for imparting predetermined height and diameter thereto, and an output (9) for the sheeted disks. Feed means (10) are further provided for feeding the dough (P, P', P") from the input (2) to the output (9). Furthermore, the presses (4, 4', 4") and the sheeting devices (6, 6', 6") are designed to be moved along the same axis (d) and substantially at the same speed as the dough (P, P', P") as they interact therewith. A method and a processing station for forming dough (P, P', P").

Inventors:
BENETTI LUIGI (IT)
Application Number:
PCT/IB2008/052027
Publication Date:
November 27, 2008
Filing Date:
May 22, 2008
Export Citation:
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Assignee:
ITECA S P A (IT)
BENETTI LUIGI (IT)
International Classes:
A21C11/00
Domestic Patent References:
WO2006129759A12006-12-07
Foreign References:
EP0463221A11992-01-02
US20050287240A12005-12-29
Attorney, Agent or Firm:
MAROSCIA, Antonio (C.trà S. Caterina 29, Vicenza, IT)
Download PDF:
Claims:

CLAIMS

1. A line for forming dough disks, such as for pizza bases or the like, comprising:

- an input (2) for at least one portion of dough (P, P 1 , P"...) to be processed;

- a first processing station (3) with at least one press (4, 4', 4") susceptible of interacting with said dough portion (P, P', P"...) to obtain a substantially disk- shaped element;

- a second processing station (5) downstream from said first station (3) having at least one sheeting device (6, 6', 6") susceptible of interacting with said pressed disk to impart predetermined height and diameter thereto;

- an output (9) for the sheeted disk;

- forwarding means (10) for advancing said dough portion (P, P', P"...) from said input (2) to said output (9); wherein said feed means (10) are designed to continuously feed said dough portion (P, P', P"...) from said input (2) to said output (9), and wherein said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") are designed to forward along the same axis (d) and in the same direction (V) as said dough portion (P, P', P"...) as they interact therewith, for processing the dough (P, P', P"...) as it moves.

2. Line as claimed in claim 1 , wherein said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") are further designed to forward substantially at the same speed as said dough portion (P, P', P"...) as they interact therewith.

3. Line as claimed in claim 1 or 2, wherein said forwarding means (10) include a single belt conveyor extending from said input (2) to said output (9).

4. Line as claimed in claim 1, 2 or 3, wherein said forwarding means (10) move said dough portion (P, P 1 , P"...) at substantially constant speed.

5. Line as claimed in any one of claims 1 to 4, comprising means (17, 17', 17") for driving said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") from a first rest position away from said dough portion (P, P', P"...) to a second work position in which they interact with said dough portion (P, P', P"...).

6. Line as claimed in claim 5, wherein said drive means (17, 17', 17") have a frame (18, 18', 18") with guide crossbars (20, 20', 20") substantially parallel to the axis of feed (d) of the dough (P, P 1 P"...).

7. Line as claimed in claim 6, wherein said drive means (17, 17', 17") further have a carriage (19, 19', 19") that slides along said guide crossbars (20, 20', 20"), said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") being mounted to said carriage (19, 19', 19").

8. Line as claimed in claim 7, wherein said carriage (19, 19', 19") comprises vertical drive means (21 , 21', 21") for vertically driving said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") from said rest position to said work position and vice versa.

9. Line as claimed in one or more of claims 1 to 8, wherein said first (3) and/or said second processing stations (5) include at least one plate (22, 22', 22") located below said feed means (10) and facing towards said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") to act as an abutment therefor during interaction with the dough (P, P', P"...).

10. Line as claimed in claim 9, wherein said at least one plate (22, 22', 22") is designed to advance substantially at the same speed as said at least one press (4, 4', 4") and/or said at least one sheeting device (6, 6', 6") during interaction with said dough portion (P, P', P"...).

11. Line as claimed in one or more of claims 1 to 10, comprising a

microprocessor-based unit for synchronizing the motion of said feed means (10) with the motion of said carriage (19, 19', 19") and said vertical drive means (21 , 21', 21").

12. Line as claimed in one or more of claims 1 to 11 , wherein said sheeting device (6, 6', 6") comprises a plurality of cones (30, 30', 30") rotating about a substantially vertical axis (X), each of said cones (30, 30', 30") also rotating about respective inclined axes (Y, Y 1 , Y") to interact with the pressed disk.

13. Line as claimed in one or more of claims 1 to 12, wherein said input (2), said first (3) and second processing stations (5) and said output (9) are arranged along a substantially horizontal and straight axis (d).

14. Line as claimed in one or more of claims 1 to 13, comprising a third processing station (7) located downstream from said second station (5) and upstream from said output (9), said third station (7) comprising at least one calibrating device (8, 8', 8") susceptible of interacting with said sheeted disk to calibrate its outer peripheral edge.

15. Line as claimed in claim 14, wherein said at least one calibrating device (8, 8', 8") is mounted to respective drive means (17") to be movable from a respective rest position to a respective work position and vice versa.

16. A method for forming dough disks, as claimed in one or more of the preceding claims, comprising the steps of: a) providing a portion of dough (P, P', P"...) to be processed; b) first processing of said dough portion (P, P', P"...) by means of at least one press (4, 4', 4") to obtain a substantially disk-shaped element; c) second processing of the disk so obtained by means of a sheeting device (6, 6', 6") to impart predetermined height and diameter thereto; wherein, during said first and/or said second processing steps, said dough portion (P, P', P"...) is continuously advanced, and wherein said at least one press (4, 4', 4") and/or said at least one sheeting device

(6, 6', 6") are designed to advance substantially along the same axis (d) and in the same direction (V) as said dough portion (P, P', P"...) as they interact therewith.

17. Method as claimed in claim 16, wherein said method comprises a step of calibration of the outer peripheral edge of said sheeted disk by means of at least one calibrating device (8, 8', 8").

18. Method as claimed in the preceding claim, wherein during said calibration step said dough portion (P, P', P"...) is forwarded continuously, said at least one calibrating device (8, 8', 8") being designed to be fed along the same axis (d) and in the same direction (V) as said dough portion (P, P', P"...) as it interacts therewith.

19. Method as claimed in claim 16, wherein said dough portion (P, P', P"...) forwards at a substantially constant speed.

20. Method as claimed in claim 16, wherein said dough portion (P, P', P"...) has a speed of 100 to 200 mm/sec.

21. A station for processing dough, such as for pizza or the like, comprising:

- an input (2) for at least one portion of dough (P, P', P"...) to be processed;

- at least one processing head, susceptible of interacting with said dough portion (P, P 1 , P"...) to obtain a processed product;

- an output (9) for the processed product;

- forwarding means (10) for advancing said dough portion (P, P', P"...) from said input (2) to said output (9); wherein said forwarding means (10) are designed to continuously advance said dough portion (P, P', P"...) from said input (2) to said output (9), and wherein said processing head is designed to advance along the same axis (d) and in the same direction (V) as said dough portion (P, P', P"...) as it interacts therewith, for processing the dough as it moves.

22. Processing station as claimed in claim 21 , wherein said processing head comprises at least one press (4, 4', 4"), at least one sheeting device (6, 6', 6") or at least one calibrating device (8, 8', 8") respectively.

Description:

LINE, METHOD AND PROCESSING STATION FOR FORMING DOUGH DISKS, SUCH AS PIZZA BASES OR THE LIKE

Field of invention

The present invention finds application in food processing industry, and particularly relates to a line for forming dough disks, such as pizza bases or the like.

In another aspect, the invention relates to a dough forming method and a processing station therefor.

Background Art

The process of forming dough disks, such as pizza bases or the like includes two sequential basic steps: pressing and sheeting.

Pressing is aimed at imparting a substantially disk-like shape to the starting dough portion, which is usually of substantially spheroidal shape. On the other hand, sheeting is designed to impart the desired height and diameter, possibly differing as needed, to the pressed dough.

Nowadays, due to technological reasons, forming is carried out using several different machines operating on various belt conveyors, possibly arranged orthogonal to each other. Particularly, dough forming is generally carried out while the dough is still at the relevant machines.

One drawback of the prior art forming lines is that they have a relatively low production rate. By contrast, their size and costs are unacceptably high.

Another drawback is associated with the multiple conveyors that are used particularly for feeding the product through the various stations of the line. As the product passes from one belt to the other it inevitably loses its right working

position and requires realignment to be properly presented to the various processing stations.

Furthermore, the multitude of belts that are provided creates a number of mechanical complications.

Summary of the invention

The object of this invention is to overcome the above drawbacks, by providing a line for forming dough disks that is highly efficient and relatively cost-effective.

A particular object is to provide a line that affords minimized space requirements and maximized throughput.

Another object is to provide a line that involves minimized stresses on the dough, and hence maintains its organoleptic characteristics almost unchanged.

A further object of the invention is to provide a method that ensures repeatability during production.

Yet another object of the invention is to provide a processing station that affords maximized production rate.

These and other objects as more clearly shown hereafter, are fulfilled by a forming line as defined in claim 1, comprising an input for at least one portion of yeast dough, a first processing station with at least one press susceptible of interacting with the dough portion to obtain a substantially disk-shaped element, a second processing station, downstream from the former, having at least one sheeting device susceptible of interacting with the pressed disk for imparting predetermined height and diameter thereto, an output for the sheeted disk and forwarding means for advancing the dough portion along a substantially horizontal axis from the input to the output.

According to the invention, the forwarding means are designed for continuously forwarding the dough portion from the input to the output. The press and/or the sheeting device are also designed to be fed along the same axis and in the same direction as the dough portion as they interact therewith.

Thanks to this particular configuration, the forming line of the invention has minimized space requirements and ensures maximized throughput. Since the dough is processed as it moves, production occurs continuously and is thus maximized, and especially the use of storage tanks, rephasers and the like can be avoided, wherefore space requirements can be minimized.

Advantageously, the press and/or the sheeting device may be also designed to be fed at substantially the same speed as the dough portion as it interacts therewith, so that no motion occurs between the dough and the press and/or the sheeting device. This will prevent stresses from being exerted on the dough, and preserve its organoleptic properties.

Suitably, the forwarding means may include a single belt conveyor extending from the input to the output of the line. This will prevent stresses from being exerted on the dough, and maintain its organoleptic properties substantially unchanged. Thanks to the provision of a single belt conveyor, the line control and drive section will be greatly simplified, thereby reducing costs and sizes. This also avoids the need for speed adjustments, as well as the use of any connecting conveyors and equipment.

In another aspect, the invention relates to a methods for forming dough disks as defined in claim 16, including the steps of: providing a portion of yeast dough, first processing said dough portion by means of at least one press for obtaining a substantially disk-shaped element, secondly processing the disk-shaped element so obtained by means of at least one sheeting device for imparting predetermined height and diameter thereto.

During the first and/or second processing steps, the dough portion is continuously advanced. Also, the press and/or the sheeting device are designed to forward along the same axis and substantially at the same speed as the dough portion as they interact therewith.

In yet another aspect, the invention provides a processing station as defined in claim 21 , comprising an input for at least one yeast dough portion, at least one processing head susceptible of interacting with the dough portion to obtain a processed product, an output for the processed product and means for feeding the dough portion dough from the input to the output.

The feed means are designed for continuously feeding the dough portion from the input to the output. The processing head is designed to forward along the same axis and substantially at the same speed as the dough portion as it interacts therewith.

Advantageous embodiments of the invention will be defined in accordance with the independent claims.

Brief description of the drawings

Further features and advantages of the invention will be more apparent upon reading of the detailed description of a preferred, non-exclusive embodiment of a line according to the invention, which is described as a non-limiting example with the help of the annexed drawings, in which:

FIG. 1 is a side view of a line of the invention;

FIG. 2 is a top view of a line of the invention;

FIG. 3 is a side view of a processing station that is part of the line of the invention, which shows the start and end positions (the latter one in broken lines) of the processing heads;

FIGS. 4 and 7 are side views of the processing station of FIG. 3, in which the

processing heads are in the rest position;

FIGS. 5 and 6 are side views of the processing station of FIG. 3, in which the processing heads are in the work position;

FIG. 8 is an axonometric view of certain details of a processing device 6, in which the protective shield 40 has been shown in broken lines.

Detailed description of a preferred embodiment

Referring to the above figures, the line of the invention, generally designated by numeral 1 , may be advantageously used for forming dough disks, such as for pizza or the like.

As shown in Figures 1 and 2, the line of the invention essentially has an input 2 for the portions of yeast dough P, P 1 , P", ..., a first processing station 3 with a plurality of presses 4, 4', 4" susceptible of interacting with the dough P, P', P", a second processing station 5, having a plurality of sheeting devices 6, 6', 6" adapted to interact with the dough that comes out of the first processing station, the third processing station 7 with a plurality of calibrating devices 8, 8', 8" adapted to calibrate the dough that comes from the second station and an output 9 for the dough so processed.

The line 1 may either or not comprise the third calibrating station 7. While reference will be made hereinafter to a line 1 that also comprises the third station 7, it shall be understood that the line 1 may also include the first and the second stations 3 and 5 only, without departure from the scope as defined in the annexed claims. If the line 1 does not comprise the third station 7, the output for the dough portion P, P', P" is located directly downstream of the second sheeting station 5.

In a preferred, non exclusive arrangement of the invention, the sheeting devices 6, 6', 6" may comprise a plurality of cones 30, 30', 30" rotating about respective axes Y, Y', Y" to interact with the previously pressed dough disks P, P', P"... .

Preferably, each device 6, 6', 6" may have three cones disposed at 120° from

each other.

The line 1 further comprises forwarding means for advancing the dough portion P, P', P", ... from the input 2 to the output 9, which may be defined by a single main belt conveyor 10 extending along a substantially horizontal straight axis d. Nevertheless, any other forwarding means may be used, such as a plurality of belt conveyors, without departure from the inventive scope as defined in the annexed claims.

A dough leavening chamber, not shown but well known per se, and a loading station 11 for loading the dough P, P', P", ... may be located upstream of the input 2 of the line 1.

The loading station 11 may include a first belt conveyor 12 for receiving the dough portions P, P', P", ... from the loading chamber and a second belt conveyor 13, located perpendicular to and below the former and substantially aligned with the belt 10. The first belt conveyor 12 is composed of a plurality of conveyor elements of different lengths, for alignment of the portions P 1 P 1 , P" ... on the second belt 13. The latter may in turn have a connecting cup device, not shown but known per se, for compensating for any misalignment caused by inappropriate loading on the first belt 12.

The load station 11 may also comprise a flour duster 14 downstream from the second belt 13 for sprinkling flour on the portion P, P', P", ... thereby preventing it from sticking with the subsequent belts. A small belt 15 may be further provided downstream from the flour duster 14, to define the input 2 of the line proper. This belt 15, inclined to the main extension plane of the belts 13 and 10, may cooperate therewith to upturn the portion P, P', P"... and lay the previously dusted face thereof on the next belt.

Another flour duster 16 may be further provided for sprinkling flour on the free surface of the dough P, P 1 , P"... to prevent it from sticking with the subsequent

processing heads.

Each processing station 3, 5 and 7 comprises means 17, 17', 17" for driving its processing heads, particularly the presses 4, 4', 4", the sheeting devices 6, 6', 6" and the calibrating devices 8, 8', 8" respectively from a first rest position away from the portions P, P', P", as shown in Figures 4 and 7, to a second work position, as shown in Figures 5 and 6, in which they interact with the dough portion P P 1 P"

According to the invention, the single belt 10 is designed to forward the dough portion P, P', P" from the input 2 to the output 9 along the axis d in a continuous manner, i.e. with no stops. Preferably, the belt 10 is designed to feed the dough P, P', P"... at substantially uniform and constant speed.

Furthermore, the processing heads of the stations 3, 5 and 7 will be designed to be advance along the same axis d and preferably substantially at the same speed as the dough portion P, P', P"... (and hence as the single belt 10) as they interact therewith, to allow processing of the dough as it moves.

For this purpose, the drive means 17, 17', 17" have respective frames 18, 18', 18" above the single belt 10, adapted to support the processing heads 4, 4', 4", 6, 6', 6" and 8, 8', 8" of the processing stations 3, 5 and 7 and ensuring motion thereof.

Each frame 18, 18', 18" has a carriage 19, 19', 19" that slides along a guide crossbar 20, 20', 20" substantially parallel to the axis of advancement of the dough P, P', P"... which is horizontal in the illustrated example. The processing heads 4, 4', 4", 6, 6', 6" e 8, 8', 8" of the processing stations 3, 5 and 7 will be mounted to the carriage, which will ensure horizontal displacement thereof.

Each carriage 19, 19', 19" in turn includes means 21 , 21', 21" for vertically driving the processing heads 4, 4', 4", 6, 6', 6" and 8, 8', 8" of the processing stations 3, 5 and 7.

The combination of the horizontal motion of the carriages 19, 19', 19" and the vertical motion of the means 21 , 21', 21" allows the processing heads 4, 4', 4", 6, 6', 6" and 8, 8', 8" of the processing stations 3, 5 and 7 to move from the rest position to the work position and vice versa.

Each processing station 3, 5 and 7 may have a respective set of plates 22, 22', 22" below the single belt 10 and facing towards the processing heads 4, 4', 4", 6, 6', 6" and 8, 8', 8" to act as an abutment therefor.

The plates of the set 22, 22', 22" are integral with the carriages 19, 19', 19" via connecting crossbars 23, 23', 23", so that the carriages 19, 19', 19" can drive the plates 22, 22' and 22" in their horizontal motion. Thus, the plates will always and constantly face towards the processing heads 4, 4', 4", 6, 6', 6" and 8, 8', 8" as they interact with the dough portion P, P', P"... for proper processing thereof.

An unloading station, possibly similar to the loading station 11, may be located downstream of the output 9, to lead to the next processing stations, such as for filling and baking the dough P, P', P"... .

In a preferred, non exclusive embodiment of the invention, the line 1 may include a microprocessor unit, not shown but known per se, for synchronizing the motion of the conveyor 10 with the motion of the carriages 19, 19', 19" and vertical drive means 21 , 21', 21" to make the two motions independent from each other. Such synchronization will avoid the use of means for detecting the moving dough on the main belt 10.

Figures 3 to 7 show a processing cycle of a processing station. As mentioned above, each processing station 3, 5 and 7 has respective processing heads, particularly the presses 4, 4', 4", the sheeting devices 6, 6', 6" and the calibrating devices 8, 8\ 8".

While the processing cycle as shown in Figures 3 to 7 is related to the sheeting

station 5, having respective sheeting devices 6, 6', 6", it shall be understood that both the pressing station 3 and the calibrating station 7 and hence the presses 4, 4', 4" and the calibrating devices 8, 8', 8" operate substantially in the same manner. It shall be further understood that, while Figures 3 to 7 show a processing station 5 with five sheeting devices, the latter may be provided in any number without departure from the scope of the invention, as defined by the annexed claims.

As shown in the figures, the sheeting devices 6, 6', 6" are mounted to a crossbar 28 vertically movable along threaded columns 29, 29' that define the vertical drive means 21'. Clockwise and counterclockwise motion of the threaded columns 29, 29' (in turn controlled by special motor means connected to a PLC unit, not shown but known per se) allows height adjustment of the crossbar 28 and hence of the sheeting devices 6, 6', 6".

The carriage 19' and the crossbar 28 (with the sheeting devices 6, 6', 6" integral therewith) cover respective strokes δL and δH, as shown in Figure 7, respectively along an axis substantially parallel to the axis of feed d of the dough P, P', P"... and along an axis substantially perpendicular thereto, to carry the sheeting devices 6, 6', 6" from the rest position to the work position and vice versa. Particularly, the carriage 19' will move from a start position Li to an end position l_2 and vice versa, whereas the crossbar 28 will move from a start height Hi to an end height H 2 and vice versa, as particularly shown in Figure 3.

From the rest position as shown in Figure 4, the sheeting devices 6, 6', 6" will cover the stroke δH, which is defined as the difference between the heights Hi and H 2 , to move from the rest position to the work position, and thence will interact with the dough along the section δL, which is defined as the difference between the positions L 2 and Li 1 and finally raise again by δH to the start position.

Both strokes δH and δL can be adjusted as desired, e.g. by microprocessor

programming, using a microprocessor-based unit of the PLC type. Abutment means may be further provided along both δH and δL. In the example of the figures, the two stop elements 27 and 27' are shown, which actually define the stroke δL.

The speeds of motion along both δH and δL may be also changed as desired (such as by the same PLC as mentioned above) as long as the speed of the carriage 19' will be substantially the same as the single conveyor 10 as the sheeting devices 6, 6', 6" interact with the dough P, P', P"... . The PLC may be also used to set the time intervals from one displacement to the others as desired.

In this respect, the speed of the single conveyor 10 may be synchronized with the speed of the horizontal and vertical drive means 19', 21' of the sheeting devices 6, 6', 6", for the two motions to be substantially independent of each other. In this case, the driving cycle of the sheeting devices 6, 6', 6" along both δH and δL may be also continuous and independent of the continuous motion of the dough P, P', P"... along the axis d.

Otherwise, for instance for particular production requirements, the two motions can be caused to be dependent on each other using sensor means, such as an array of proximity sensors, so that the sheeting devices 6, 6', 6" will be only driven if the sensors detect the dough P, P', P"....

The various positions as mentioned above will be now described in detail.

Figure 4 shows a start rest position of the sheeting devices 6, 6\ 6". In this position, the sheeting devices 6, 6', 6" are at their maximum height Hi and the carriage 19' abuts against the stop element 27 in the position L|. The height H-i is defined such that the cones 6, 6', 6" are at such a height that they do not interact with the dough P, P', P".... The latter comes from the previous station 3 and enters the workstation 5 on the belt 10, along the axis d and in the direction V,

preferably at a substantially constant speed. The surface plates 22' face towards the cones 6, 6', 6" which are also in the position L 1 .

After a first predetermined time, that can be set by the above mentioned PLC, the threaded columns 29, 29' will vertically drive (along the arrow Fi) the crossbar 28, and the sheeting devices 6, 6', 6" therewith, from the rest position at the height Hi to the work position, at the height H 2 , in which the sheeters 6, 6', 6" are in contact with the dough P, P', P".... This situation is shown in Figure 5. The surface plates 22' are always in the position Li . In this position, the sheeters 6, 6', 6" will start processing of the dough P, P', P"... , to reduce its thickness and increase its width.

Interaction between the sheeters 6, 6', 6" and the dough P, P', P" ... will occur continuously along the axis d and in the direction V. For this purpose, after a second predetermined time (that may be very short), with the dough still seamlessly moving on the single belt 10, the carriage 19' will move from the start position L 1 to the end position L 2 as shown in Figure 6, following the arrow F 2 , along the axis d and in the direction V. The plates 22', integral with the carriage 19' will move in the same direction as the crossbeam 28 and the sheeters 6, 6', 6" to act as abutments therefor. During this step, the carriage 19' (and hence ther crossbeam 28, the sheeters 6, 6', 6" and the plates 22') and the single belt 10 will have substantially the same speed, to prevent exertion of stresses on the dough P P 1 P"

Now, after a third predetermined time, that will be long enough for the carriage 19' to reach the position L 2 , the threaded columns 29, 29' will vertically drive (along the arrow F 3 ) the crossbar 28, and the sheeting devices 6, 6', 6" therewith, from the work position at the height H 2 to the rest position, at the height H 1 , in which the sheeters 6, 6', 6" are away from the dough P, P', P"... and not in contact therewith. This situation is shown in Figure 7. The surface plates 22' are always in the position L 2 . The dough P, P', P", ... will still move on the single belt 10 along the axis d and in the direction V to the next calibration station 7, whereas more dough from the previous pressing station 3 will enter the sheeting station 5 for

processing.

For this purpose, after an additional predetermined time, the carriage 19' will move along the arrow F 4 to carry the crossbeam 28 and the sheeters 6, 6', 6" and the surface plates 22', from the position L 2 to the start position Li, still along the axis d, but in a direction V opposite to V. Advantageously, this motion may be very fast, in view of minimizing dead times and maximizing throughput.

Once the carriage 19' has reached the position Li, the cycle will restart anew.

The line 1 process the dough P, P', P"... using a method that includes the following steps.

First the portions P, P', P'... are manually or automatically fed to the loading station

11 from the leavening chamber. Then, the portions P, P', P"... are laid on the belt

12 and move therefrom along an axis substantially perpendicular to d, to the underlying belt 13. Here, they may be stopped and realigned to be next fed on the same belt 13 along the axis of feed d in the direction V.

The portions P, P', P"... will be first submitted to a first leveling step by the leveler 25, whose function is to minimize the stresses that will be exerted on the dough by the subsequent pressing step, and to a first flour dusting step by the flour duster 14.

Then the portions P, P', P"... will reach the edge of the belt 13 and fall by gravity onto the small underlying belt 15 face down, so that the previously flour-dusted face defines the contact surface of the dough P, P', P"... with the belt.

The belt 14 will move along the axis d and in the direction V to carry the dough portions P, P', P"... to the input of the single main belt 10 that moves along the same axis and in the same direction as the belt 15. In a preferred, non exclusive configuration of the invention, the single belt 10 will move continuously at a

substantially constant speed, preferably from 100 to 200 mm/sec.

Thus, as the dough portions P, P, P" are fed along the axis d in the direction V, they will be first submitted to a second flour dusting step by the flour duster 16 and will then enter the first work station 3.

All the above steps upstream of the latter will aimed at preparing the dough portions P, P', P"... for further processing.

As used herein, the term "preparing" and derivatives thereof, designates the preparation of a relevant element for a relevant process step, including any preventive treatment designed for optimal performance of such relevant step, from simple collection and possible storage to thermal and/or chemical and/or physical and the like pre-treatments.

At the first work station 3, the presses 4, 4', 4" will move from the rest position to the operating position to process the dough P, P', P"... from a substantially ball or egg shape into a substantially disk-shaped element, as they move along the axis d and in the direction V.

For this purpose, each press 4, 4', 4" may have an end hammer for pressing the dough P, P', P"... with predetermined force.

Then, the disk-shaped dough P, P 1 , P"... moves on the single belt 10, along the axis d and in the direction V from the output of first processing station 3 to the input of the second processing station 5.

Now, the sheeting devices 6, 6', 6" will move from the rest position to the operating position to impart predetermined height and diameter to the previously pressed dough disks P, P', P"... . This step is carried out as they move along the axis d and in the direction V.

For this purpose, in a preferred, non exclusive arrangement of the invention, the sheeting devices 6, 6', 6" may comprise a plurality of cones 30, 30', 30" rotating about a substantially vertical axis X, as shown in Figure 8. Each cone 30, 30', 30" also rotates about an inclined axis Y, Y', Y" to interact with the previously pressed dough disks P, P', P"... Preferably, each device 6, 6', 6" may include three cones arranged at 120° from each other. The cones of each device 6, 6', 6" may be further protected by a case 40.

Then, the dough P, P', P".., still moving on the single belt 10, leaves the second processing station 5 to reach the input of the third processing station 7.

Now, the calibrating devices 8, 8', 8" will move from the rest position to the operating position to calibrate the outer peripheral edge of the dough portions P, P', P"... as the latter still move along the axis d in the direction V.

For this purpose, the calibrating devices 8, 8', 8" may be of traditional type, i.e. composed of a plurality of adjacent elements that define a circumference, and are mutually movable to process the dough P, P', P"... at its peripheral edge for calibration.

The above disclosure clearly shows that the line and method for forming dough disks according to the invention fulfils the intended objects and particularly the object of minimizing space requirements and maximizing throughput.

The line and method of the invention afford more than 50% reduced space requirements with the same throughput or above 50% higher throughput with the same space requirements.

Another apparent advantage of the line and method of the invention is that the various processing stations may be arranged along a substantially horizontal direction, thereby reducing space requirements and minimizing the space volumes occupied thereby.

The line and method of the invention are susceptible to a number of changes and variants, within the inventive concept disclosed in the annexed claims. All the details thereof may be replaced by other technically equivalent parts, and the materials may vary depending on different needs, without departure from the scope of the invention.

While the line and method have been described with particular reference to the accompanying figures, the numerals referred to in the disclosure and claims are only used for the sake of a better intelligibility of the invention and shall not be intended to limit the claimed scope in any manner.