DEVICE FOR FORMING A SHEETED DOUGH FROM A DOUGH PIECE BY PRESSING

Abstract

A device for forming a sheeted dough from a dough piece, which includes: (i) a lower tray arranged so as to support the dough piece during a forming operation, (ii) an upper tray, and (iii) a forming actuator arranged so as to move the upper plate in relation to the lower plate, in such a way as to be able to press the dough piece between the lower tray and the upper tray in order to form a sheeted dough, the lower tray containing a system of mobile ejectors that can assume a so-called retracted position in such a way as to form, overall, a continuous surface with the lower tray, and a so-called raised position in such a way as to form a raised surface in relation to the lower tray.

Claims

1. A device for forming a sheeted dough from a dough piece, comprising: a lower platen, arranged to support the dough piece during a forming operation; an upper platen; a forming actuator, arranged to generate a relative movement between the upper platen and the lower platen, so that the dough piece can be pressed between the lower platen and the upper platen to form a sheeted dough; the lower platen comprises: a pressure plate having an upper surface suitable for receiving the dough piece, the pressure plate being equipped with a plurality of apertures formed in the upper surface thereof; a plurality of moveable elements, each moveable element engaging with one of the apertures in the pressure plate, the moveable elements being suitable for adopting: a position known as retracted position, in which an upper surface of each moveable element is flush with the upper surface of the pressure plate, in such a way as to form, overall, a continuous surface with the pressure plate; and a so-called raised position, in which the moveable elements protrude with respect to the upper surface of the pressure plate, in such a way that the upper surfaces of each moveable element together form a raised surface with respect to the upper surface of the pressure plate; and a lifting device, arranged to move the moveable elements with respect to the pressure plate, in such a way that the moveable elements adopt the retracted position or the raised position.

2. The device according to claim 1, characterized in that the sum of the upper surface areas of the moveable elements is comprised between 4% and 96% of the total surface area of the pressure plate.

3. The device according to claim 1, characterized in that the upper surfaces of the moveable elements together form a connected surface.

4. The device according to claim 1, characterized in that the upper surfaces of the moveable elements together form a disconnected surface, each moveable element being evenly spaced from the nearest neighbouring moveable element in at least one direction.

5. The device according to claim 1, characterized in that each moveable element comprises a stud arranged inside one of the apertures of the pressure plate, the studs being capable of being moved in translation along an axis perpendicular to the upper surface of said pressure plate.

6. The device according to claim 5, characterized in that the lower platen is arranged so that there is clearance between the stud of each moveable element and the corresponding aperture of the pressure plate.

7. The device according to claim 2, characterized in that the lifting device comprises a support plate on which the moveable elements are mounted, and an actuator arranged to move the support plate so that the moveable elements can successively adopt the retracted position and the raised position.

8. The device according to claim 1, characterized in that it comprises a first heating means arranged to heat the upper platen.

9. The device according to claim 1, characterized in that it comprises a second heating means arranged to heat the lower platen.

10. The device according to claim 1, characterized in that the upper platen and/or the lower platen comprise a material having a thermal conductivity greater than or equal to 50 W/m.K, such as for example aluminium, an aluminium alloy or copper.

11. The device according to claim 1, characterized in that the upper platen and/or the lower platen comprise a non-stick coating at least on the facing surfaces thereof.

12. The device according to claim 1, characterized in that it comprises a device for adjusting the size of the sheeted dough, said device comprising: storage means arranged to store a plurality of upper platens, each upper platen having on a lower surface thereof a recess of a predetermined size; and a loading mechanism arranged to move one of the upper platens between the storage means and a position in which is it attached to the forming actuator.

13. Use of the device according to claim 1 to press a dough piece of the pizza dough type in order to form a sheeted dough.

14. An automated machine for preparing at least one pizza, comprising: a system for preserving and metering ingredients, said ingredients being suitable for use in preparing pizzas; a device for forming a sheeted dough according to claim 1; an oven, arranged to cook at least one pizza; a handling system arranged to transfer at least one of the pizzas between the preservation and metering system, the forming device and the cooking oven; and a processing unit programmed to control the automated machine so as to make the at least one pizza according to a predetermined recipe.

Description

DESCRIPTION OF THE FIGURES AND EMBODIMENTS

[0064] Other advantages and characteristics of the invention will become apparent from the following description and from several embodiments given by way of non-limitative example with reference to the attached diagrammatic drawings, in which:

[0065] FIG. 1A shows a perspective view of the forming device according to the invention,

[0066] FIG. 1B shows a perspective view of a peel arranged to extract a dough sheeted by the forming device according to the invention, said peel engaging with said forming device,

[0067] FIGS. 2A and 2B show two different embodiments of the lower platen, and more particularly two particular moveable element layouts,

[0068] FIG. 2C shows a detailed view of the assembly of the moveable elements inside the lower platen, in such a way as to show the clearances that make it possible to overcome the stresses linked to the thermal expansion differences between the elements of said lower platen,

[0069] FIGS. 3, 4, 5 and 6 respectively show the first, second, third and fourth steps of the method for forming a sheeted dough from a dough piece, using a device according to the present invention,

[0070] FIG. 7 shows the incorporation of the forming device according to the invention into an automated machine for preparing culinary preparations.

[0071] The embodiments which will be described below are in no way limitative; it is possible in particular to imagine variants of the invention comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art. This selection comprises at least one, preferably functional, characteristic without structural details, or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art.

[0072] In particular, all the variants and all the embodiments described can be combined together if there is no objection to this combination from a technical point of view.

[0073] In the figures, the elements common to several figures retain the same reference.

[0074] With reference to FIG. 1A, the forming device 100 according to the invention comprises a frame 101, a lower platen 110, an upper platen 120, and a forming actuator 130. The frame 101 comprises a base 102, a first platform 103, and a second platform 104. The platform 103 is fixed in a raised position with respect to the base 102 by lateral uprights 105. It forms a support for the lower platen 110. The platform 104 is fixed in a raised position with respect to the first platform 103 by posts 106 secured to the base 102. The platform 104 forms a support for the upper platen 120.

[0075] The lower platen 110 is arranged to receive a dough piece and form a support for this dough piece during a forming operation. It comprises a pressure plate 111, an ejector plate 112 and a lifting device 113. The pressure plate 111 has an upper surface 111A suitable for receiving the dough piece. It comprises a plurality of through apertures 1111 extending through the thickness thereof. The pressure plate 111 is secured to the first platform 103 by means that are not shown. The ejector plate 112 comprises a support plate 1121 and a plurality of studs 1122 extending vertically from an upper surface 112A of the support plate 1121. The studs 1122 have a cylindrical form here. They are aligned with respect to each other in a grid of rows and columns. The ejector plate 112 is mounted in slidable connection with respect to the frame 101, by means of four guide shafts 1123 each mounted in pivoting, slidable connection on the first platform 103. A first end of the guide shafts 1123 is fixed to the support plate 1121. The lifting device 113 is arranged to move the ejector plate 112 with respect to the frame 101, and therefore with respect to the pressure plate 111. It comprises a jack 1131 the body of which is fixed to the base 102, and a motion conversion mechanism 1132 arranged to convert a horizontal translational motion into a vertical translational motion. The motion conversion mechanism 1132 comprises two guide parts 1133 and four rollers 1134. The rollers 1134 are in pivoting connection with the guide shafts 1123 of the ejector plate 112 along first horizontal axes, parallel to each other. The guide parts 1133 are in sliding connection with the base 102 along a second horizontal axis, perpendicular to the first horizontal axes. They each comprise a running surface on which one of the rollers 1134 can run. The running surfaces extend along third horizontal axes, parallel to the second horizontal axis, and have a variable profile in the vertical direction, so that the running of the rollers results in places in a vertical movement of these rollers, and therefore of the ejector plate 112 with its studs 1122. A free end of the piston of the jack 1131 is fixed to the guide parts 1133. The jack 1131 is arranged to move the guide parts 1133 along the second horizontal axis. The lower platen 110 thus allows the studs 1122 to successively adopt a retracted position, in which the upper surface thereof is flush with the upper surface 111A of the pressure plate 111, and a raised position, in which they protrude with respect to the pressure plate 111.

[0076] The upper platen 120 is arranged so that it can move vertically in translation, in such a way as to flatten a dough piece situated on the lower platen 110. It comprises a plate 121, and two linear guide shafts 122 extending vertically from an upper surface 121A of the plate 121. The linear guide shafts 122 are each in sliding connection with the second platform 104 along a vertical axis. As a result, the upper platen 120 is in sliding connection along a vertical axis.

[0077] The forming actuator 130 is arranged to drive the movement of the upper platen 120 with respect to the frame 101 between a position known as extended position, in which the upper platen 120 is sufficiently close to the lower platen 110 to allow the pressing of a dough piece, and a position known as withdrawn position, in which the upper platen 120 is far enough away from the lower platen 110 to allow the insertion of a dough piece, and the removal of a sheeted dough. The forming actuator 130 comprises a fixing frame 131, a motor 132 and a driving screw 133. The fixing frame 131 is fixed to the pistons 122. The motor 132 comprises a shaft capable of rotating along a vertical axis of rotation. The driving screw 133 is rotatably secured to the shaft of the motor 132. It could also be connected to the shaft by a reduction gear. The driving screw 133 is in pivoting connection with the fixing frame 131 by means of a ball bearing 134, in helical connection with the second platform 104 by means of a nut 135 integral with the second platform 104, and in pivoting connection with the upper platen 120 by means of a ball bearing 136. The axis of these three connections is the vertical axis of rotation of the motor 132.

[0078] In an alternative embodiment, the forming actuator could comprise one or more jacks integral with the second platform 104, a piston of each jack being fixed to the upper platen 120.

[0079] FIG. 1B shows a perspective view of a peel 150 arranged to extract a sheeted dough 320 formed by the forming device 100 according to the invention, said peel 150 engaging with said forming device 100.

[0080] More particularly, the peel 150 comprises a straight first end 151 forming a handle at the end of which a convex frame 152 extends. The peel 150 also comprises a so-called removal surface 155 formed by a two-dimensional comb extending from the convex frame 152. The comb comprises a plurality of prongs 153, for example in the form of straight bars, extending in parallel directions. The distance between two adjacent prongs is constant and preferably identical to the distance between two adjacent moveable elements on the support plate 1121 of the lower platen 110. In addition, the width of each prong 153 is smaller than the space left free between two adjacent moveable elements, in such a way as to allow the comb to be inserted laterally between the moveable elements of the lower platen.

[0081] The thickness of all of the prongs 153 is preferably constant. The thickness of the prongs 153 is preferably slightly smaller than the height of the moveable elements 1122 with respect to the pressure plate 111 when they are in their raised position as described in FIG. 6, so that it is possible to insert the peel 150 between the pressure plate 111 and the sheeted dough 320, each prong 153 of the peel 150 being inserted between two consecutive rows of moveable elements 1122.

[0082] FIGS. 2A and 2B describe two different embodiments of the lower platen 110, and more particularly two particular moveable element layouts on the surface of the support plate 1121.

[0083] In the first embodiment (FIG. 2A), the moveable elements implemented form a disconnected surface. The moveable elements are made up of a grid of identical cylindrical studs 1122 with a circular cross-section. They are organized in a regular, periodic layout in both directions of the plane formed by the upper surface 112A of the support plate 1121. For such an embodiment, the pressure plate 111 (not shown) has a grid of apertures in an identical layout to the grid of moveable elements shown in FIG. 2A. The studs typically have a diameter of the order of 10 mm. In addition, the sizing of the pressure plate and the positioning of the moveable elements with respect to said pressure plate are arranged to ensure the existence of minimum clearance between the studs and the apertures with which they engage in order to allow unrestricted sliding despite the thermal expansion of the various elements (pressure plate and moveable elements) and to prevent the dough from entering therein during the pressing operation.

[0084] Typically, the different moveable elements are positioned with respect to the pressure plate with a tolerance of the order of one hundredth of a millimetre, and the clearance between each moveable element and the aperture of the pressure plate with which it engages is of the order of 30 m.

[0085] In the second embodiment (FIG. 2B), the moveable elements implemented form a connected surface. The moveable elements adopt the form of a two-dimensional comb protruding with respect to the upper surface 112A of the support plate 1121. The comb 200 comprises a plurality of prongs 201 in the form of straight bars extending in parallel horizontal directions, and a peripheral rim portion 202 connecting the prongs 201. The connection of the upper surface of the moveable elements is provided by the peripheral rim 202.

[0086] Comparably to the embodiment described above with reference to FIG. 2A, the pressure plate 111 (not shown) has an aperture the geometry of which is complementary to the shape of the prongs 202, so that the prongs can slide freely inside this aperture. In addition, the sizing of the pressure plate and the positioning of the moveable elements with respect to said pressure plate are arranged to ensure the existence of minimum clearance between the studs and the apertures with which they engage, despite the thermal expansion of the various elements (pressure plate and moveable elements) and to prevent the dough from entering therein during the pressing operation.

[0087] FIG. 2C shows a detailed view of the assembly of a moveable element inside the lower platen, in such a way as to show the clearances that make it possible to overcome the stresses linked to the thermal expansion differences between the elements of said lower platen.

[0088] On the example shown in FIG. 2C, the moveable element 1122 is mounted on the support plate 1121 of the lower platen with very little vertical clearance h, of the order of several tenths of a micron. This clearance makes it possible to correct any misalignment of the axis of the moveable element 1122 with the axis of the aperture 1111 arranged in the pressure plate 111. The lateral clearance d is larger, of the order of one millimetre, so that the thermal expansion differences between each moveable element 1122, the support plate 1121 and the pressure plate 111 do not prevent each moveable element from sliding inside the through aperture 1111 made to this end in the pressure plate 111 as described in detail above. In other words, the vertical and transverse clearances on the support plate 1121 are such that they allow each moveable element 1122 to align automatically with the corresponding through-hole in the pressure plate 111, despite any thermal expansion differences between these elements.

[0089] On the pressure plate 111, minimum clearance is provided in such a way as to allow the moveable element to slide while preventing chilled dough from becoming inserted inside said through-hole.

[0090] On the example shown in FIG. 2C, the moveable element 1122 is mounted on the support plate 1121 by means of a screw 1124.

[0091] The forming method using the forming device according to the invention will now be described with reference to FIGS. 3, 4, 5 and 6, which show the forming device in profile cross-sectional views in different configurations.

[0092] During the first step of the method shown diagrammatically in FIG. 3, the lower platen 110 is far enough away from the upper platen 120 to allow the insertion of a dough piece 320. The dough piece is preferably placed at the centre of the pressure plate 111. The moveable elements supported here by the support plate 1121 are placed in the retracted configuration in order to form a flat surface with the pressure plate 111. To this end, the jack 1131 is actuated to position the rollers 1134 in a recess of the running surfaces 330.

[0093] It can also be seen in this figure that the upper platen 120 comprises a sunken recess formed on the inner surface 121B thereof, making it possible to obtain a sheeted dough with a desired form during the forming operation. More particularly, the upper platen 120 comprises a recess 311 formed on the peripheral rim of the surface 1216, in order to produce a crust on the rim of the sheeted dough. By way of non-limitative example, the depth of the peripheral recess 311 is comprised between 4 and 8 mm. A shallower central recess 312 is made on the entire surface situated inside the peripheral recess 311. Preferentially, the depth of the central recess 312 is constant. Alternatively, the depth of the central recess 312 can be variable and irregular in order to simulate the artisanal sheeting of a dough piece. By way of non-limitative example, the depth of the central recess 312 is comprised between 1.5 mm and 3 mm.

[0094] The second step of the forming method is illustrated in FIG. 4. The configuration of the forming device 100 is unchanged from the configuration described in the previous step, apart from in that the upper platen 120 is lowered so that the dough piece 320 is pressed between the surface formed by the pressure plate 111 and the moveable elements 1122 on the one hand, and the upper platen 120 on the other hand. In this way, the dough piece is flattened inside the closed volume comprised between these elements and therefore adopts the corresponding form, occupying both the entire volume of the central recess 312 and the volume of the peripheral recess 311.

[0095] The third step of the forming method is illustrated in FIG. 5. The configuration of the forming device 100 is unchanged with respect to the configuration described in the previous step, apart from in that the upper platen 120 is now raised in such a way as to release the sheeted dough on its upper portion. The sheeted dough has adopted the form of the mould during the previous step and therefore comprises a central portion 522 that is thinner than the peripheral rim 521.

[0096] The fourth step of the forming method is illustrated in FIG. 6.

[0097] The purpose of this fourth step is to raise the sheeted dough with respect to the pressure plate 111 in such a way that a peel can subsequently be introduced between said pressure plate and the sheeted dough, without touching the latter. To this end, the moveable elements 1122 must therefore be moved to their raised position. The jack 1131 is actuated to position the rollers 1134 on an upper portion of the running surfaces 330.

[0098] Optionally, the guide parts 1133 can be arranged in such a way as to define several intermediate configurations of the ejector plate 112. They comprise for example a plurality of horizontal planes situated at different heights and making it possible to define stable positions translating particular heights of the moveable elements above the pressure plate 111.

[0099] FIG. 7 describes the use of a forming device according to any one of the improvements mentioned above in an automated machine for preparing culinary preparations.

[0100] The automated machine for preparing culinary preparations 700 can in particular be arranged to prepare, cook and/or package and/or deliver culinary preparations. It applies in particular to preparing culinary preparations comprising a sheeted dough, and particularly pizzas.

[0101] The automated machine for preparing culinary preparations, also known as the automaton 700, comprises: [0102] a system 701 for preserving and metering ingredients, said ingredients being suitable for use in preparing said culinary preparations; [0103] a forming device 100 according to any one of the improvements of the present invention; [0104] an oven 702, arranged so that it can cook the culinary preparations; [0105] a box dispenser 703; [0106] a handling system 704-706, arranged so that it can transfer at least one of the made up culinary preparations in particular between the system 701 for preserving and metering ingredients and the oven 702 in particular; [0107] a processing unit programmed to control said automated machine so as to prepare a culinary preparation according to a predetermined recipe.

[0108] For ease of understanding, an example will be given for the preparation of a pizza, but the automated machine is arranged to prepare a wide variety of culinary preparations, as mentioned above.

[0109] In the example shown in FIG. 7, the automated machine 700 also comprises a chilled dough tank 708. The handling system implemented comprises in particular three multi-axis robotic arms 704, 705, 706. These robotic arms are arranged to handle the pizza being made, for example by means of a peel 709, and to transfer it from one station to another.

[0110] Thus, during a first step, a predetermined quantity of dough, preferably chilled, is extracted from the tank 708 to form a dough piece. This predetermined quantity is sized so that the dough piece can be flattened to the desired dimensions of a pizza dough.

[0111] The robotic arm 705 can be equipped with a peel, referred to as a dough peel, to transfer the dough piece to the forming device 100. More precisely, the robotic arm 705 places the dough piece on the lower platen 110. The forming device 100 presses the dough piece to form a sheeted dough by lowering the upper platen 120. The lifting device 113 then places the moveable elements 1122 in the raised position.

[0112] The automated machine 700 can also comprise means for placing a sauce (for example tomato- or fresh cream-based) on the sheeted dough.

[0113] A conveyor 712 can then be equipped with a peel, for example a comb-shaped peel, to transfer the sheeted pizza dough to the preservation and metering system 701. Said system 701 is arranged to place quantities of ingredients determined according to a given recipe on the surface of the dough.

[0114] The robotic arm 705 can then transfer the pizza from the system 701 to the oven 702.

[0115] The oven 702 can be arranged to cook a pizza according to a cooking cycle depending on cooking parameters determined according to the recipe selected. The cooking parameters include for example a cooking time and temperature.

[0116] The robotic arm 706 can be arranged to extract boxes 711 individually from the box dispenser 703, and place them on a packing station 710.

[0117] At the end of the cooking cycle, the door of the oven 702 is opened, and the robotic arm 704 removes the pizza from the oven 702 using a peel. The robotic arm 704 then places the pizza in a box 711 placed on a packing station 710.

[0118] The robotic arm 706 can also be arranged to slice the pizza placed in the box 711, and/or season it with condiments.

[0119] Of course, the invention is not limited to the examples which have just been described and numerous adjustments can be made to these examples without exceeding the scope of the invention. In particular, the different characteristics, forms, variants and embodiments of the invention can be combined with one another in various combinations to the extent that they are not incompatible or mutually exclusive. In particular all the variants and embodiments described previously can be combined together.