This application relates to a method, apparatus and mold for producing a confectionery product.
In the field of confectionery, products are known which are made from chocolate or other lipid-based material and have a two-piece structure. For example, a shell can be produced first, filled with an appropriate filling such as fruit puree, liquor or caramel and closed with a lid. Other confectionery products, both filled and hollow, require two lipid-based moulded parts to be joined together around their perimeters.
U.S. Pat. No. 3,962,473 describes a method of making crust liqueurs, in which liquid filling is deposited in chocolate shells, which are closed by pouring liquid chocolate so as to produce a lid. As far as the bonding between the lid and the shell is concerned, the described method relies on the bond between the molten and, therefore, warm chocolate which is poured to produce the lid, and the edge of the shell, which is generally cold.
In this regard, DE 3444060 A1 describes a method and apparatus, in which a filled confectionery product is produced by forming a shell and filling same. Afterwards, the shell is passed through a heating station to heat the edges of the shell before the lid is applied by pouring molten chocolate on the shell and the filling. Experiments have shown that the bonding strength of products made in the aforementioned way is sometimes insufficient.
There is provided a method, apparatus and mold for producing confectionery products from two (or more) pieces, through which the bonding between the two pieces, such as the shell and the lid, can be enhanced by applying heat directly, and exclusively to the joint between the two pieces.
In particular, there is provided a method for producing a confectionery product from at least two pieces with at least one interface, joint or seam between the two pieces. The two pieces can, for example, be two moulded shell halves (e.g. a hollow Easter egg); a filled or hollow shell and a lid where the lid is a flat “solid” piece of chocolate or other material; or a filled shell containing e.g. a fruit or caramel, with a sealing layer (e.g. chocolate) initially deposited as a liquid material. Further, the confectionery product to be produced by the novel method includes meltable material, such as dark or white chocolate or another lipid-based material in at least parts of the interface. The bonding strength between two pieces of confectionery product can be advantageously increased when the interface is heated during or after the pieces involved have been brought into contact with each other. Thus, in principle, the surfaces of the pieces which abut each other at the interface, are heated and melted to some extent, and held in that molten state for a sufficient time to allow the molten regions to merge, resulting in the formation of a strong bond when they are cooled afterwards.
As experiments have shown, this measure provides an improved bonding between the pieces from which the confectionery product is made, for example a shell and a lid of a filled praline, so that the filling will not leak, even if some mechanical stress is applied, for example during handling of the product. It has also been found that the above-described heating does not affect the temper of the chocolate. Without wishing to be constrained to any particular theory, it is believed that good bonding between two surfaces of chocolate requires adequate heat be applied to bring the chocolate on both surfaces to the molten state, and that sufficient time be allowed for these molten regions to comingle and form a homogenous layer prior to cooling. Thus, the method described herein is based on, but not limited to, the idea of heating the one or more interfaces between two or more pieces of a confectionery product, in other words the seam area(s) locally. In this respect, the seam area(s) may be located in a mold or form, which may comprise a heatable component, such as a metallic foil heatable by induction heating. However, the mold or form is not absolutely necessary. Rather, for example, a metallic foil or component may be present at the seam area(s) and heatable so as to realize the method described above. The mentioned foil, which may be applied as a tape around the perimeter of the surface to be heated, may be part of a decoration and may stay on the product until the product is consumed. It may also be a part of an outer wrapping, for example of cellophane, and may be separated from the product only when it is sold or consumed.
Currently, particularly good results have been achieved when performing the heating in the area of the interface by induction heating. This method can also be called indirect heating as the entire mold, in which the confectionery product is located, does not need to be heated or to be equipped with a heater in a strict sense. Rather, an appropriate portion or component, such as a thin strip of aluminum foil, can be present in the mold, in particular at the area to be joined. When such a mold with the two-piece confectionery product embedded therein passes through an induction heater, heat is produced only in the mentioned component, not in the confectionery product itself, so that only that part of the confectionery product which is near this component is heated. This is advantageous over other known methods of sealing confections in that the heating is localized and occurs only where the component is placed and only where heat is required for joining the parts. The duration of heating can be easily controlled since the component, particularly when in the form of a foil, has little mass, and thus retains little residual heat when the electromagnetic energy is removed. This provides control over the heating time, minimizes the risk of overheating areas adjacent to the sealing area, prevents de-tempering of the chocolate and avoids melting more of the product than is necessary to create a good seal. Lastly, this method allows the joined pieces to cool relatively quickly so as to expedite extraction from the mold. In particular, the induction heater may have a coil which is energized with a radio frequency electric current. This may generate a high frequency electromagnetic field that acts on either an electrically conductive or a ferromagnetic work piece. In an electrically conductive work piece the heating effect is based on resistive heating which occurs due to magnetically induced currents called eddy currents. In a ferromagnetic work piece, the heating is mainly caused by hysteresis as the magnetic component of the electromagnetic field distorts the crystalline structure of the ferromagnetic material. The above-described effects may be combined with each other. As an example in the field of confectionery, a mold for a two-piece filled praline can be symmetrical about a vertical axis, and an induction heatable component can be present as a ring or circle near the interface between the two pieces. Thus, when the shell has been formed and filled and the lid has been applied, for example by pouring liquid chocolate, the mold with the described confectionery product may be passed through an induction heater, and the area around the interface between the shell and the lid will be heated so that at least the contact surfaces are slightly molten, and the two pieces are welded together. It has been found that the portion or component present in the mold, which is heatable by induction, does not have to be very large. Thus, this portion or component will quickly cool after heating, so that there is no interference with quick cooling and solidification of the confectionery product or its removal from the mold.
Whereas, it is also conceivable to provide and/or apply at least one piece, such as the lid as a solid piece of meltable material, such as chocolate, at least one piece of the confectionery product may be applied in liquid form, e.g. as molten chocolate. As mentioned above, the confectionery product may be formed as a product having a shell and a lid as well as a filling.
There is further described an apparatus for producing a confectionery product in which a heater may be provided downstream from a second piece forming/applying device. Thus, when using the apparatus, after a second piece, portion section or part is formed by pouring molten material or applied by bringing a solid piece in contact with a first piece, the interface between the two pieces can be heated so as to weld the two pieces together and enhance the bonding thereof. The advantageous embodiments of the apparatus substantially correspond to the above-described embodiments of the method described herein and lead to the same advantages.
This also applies to a novel mold, which is preferably used in the apparatus described above, and has at least one portion or component which is heatable by induction heating. The mold may have the general shape of a tray with plural mold cavities, i.e. recesses, in which two-piece (or more) confectionery products are accommodated. In the mold, the area at the interface of the first and the second piece is provided with a component or portion heatable by induction heating. In other words, the portion or component, which is heatable, may advantageously be located at the seam area(s) between the two or more pieces of a confectionery product. The mentioned component can, for example, be formed of a ring-like aluminum strip surrounding the mold cavity at the described interface. Thus, plural confectionery products to be made from two or more pieces can be accommodated in the described tray and can be passed through an induction heater to heat the interface between the first and the second piece, melt the material somewhat and subsequently weld it together to provide a particularly strong bond.
Finally, there is provided a heatable, preferably ferromagnetic component which is present in the vicinity of a confectionery product. As indicated above, such a component may, for example, be heated by induction heating and used to heat one or more interfaces or seam area(s) which may be present in a confectionery product, which has been made from two or more pieces. The mentioned component, which could be a metallic foil, which may be part of a product's wrapping, may, as described above, be used to heat certain portions of the confectionery product and may advantageously form part of the product's wrapping thereafter. In particular, with such a component being present at an appropriate location of a confectionery product, there may be no need for placing the product in a mold when parts thereof are to be heated.
Hereinafter will be described a non-limiting example with reference to the drawings, in which
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Dome-shaped pralines were prepared using a cocoa-butter based composition consisting of 40% cocoa butter, 53% Lactose and 7% milk protein. The shells were prepared by stamping the composition into a mold by a plunger resulting in a wall thickness of 1.4 mm. The praline shells were filled with a gelatin preparation consisting of 56.1% water, 37.4% fructose, 5.6% gelatin powder and 0.9% potassium sorbate. The filled shells were warmed for 5 secs using an infrared heater and then sealed by depositing more of the cocoa-butter based composition over the gelatin and smoothing to spread the composition to the edges of the praline. The thickness of the bottom layer was approximately 3 mm. When complete, the pralines had a bottom diameter of 27 mm and a height of approximately 24.5 mm.
The pralines were prepared for induction heating and sealing as follows: Strips of aluminum foil were prepared having a height of 5 mm and a length of 90 mm. Each strip was made from a double layer of 0.02 mm thick aluminum foil. A strip of foil was wrapped circumferentially around the bottom of the praline, and was held in place by placing the pralines, inverted, into the plastic mold originally used to form the shells. The tight fit of the praline within its mold ensured that the aluminum foil strip was in good contact with the bottom of the praline. This approach was designed to simulate the behaviour to be expected from a plastic mold having a metal strip permanently embedded in or slightly below the food contact surface. Four aluminum foil wrapped pralines were placed in the corners of a 1 mm thick, 8 cavity plastic mold, having length×width dimensions of 16 cm×8 cm.
Aluminum foil wrapped pralines, in their mold (as described above) were sealed on induction sealing equipment normally used for sealing jars (Unifoiler U6P400200000, Part# CB10461-3, Pillar Technologies, Hartland, Wis., USA). The plastic mold was conveyed under the induction sealing head, using a conveyor belt which was adjusted to provide a 10 second residence time under the induction sealing head. The plastic mold was supported on top of an empty plastic jar leaving a gap of approximately 5 mm between the plastic mold and the induction sealing head. The induction sealer was operated at a 20% power level (Maximum Power: 6000 Watts).
Evidence of melting of the cocoa butter around the perimeter of the seal area was evident after the mold emerged from the induction sealing head. The pralines were kept in their molds for 18 hours at room temperature to fully solidify before removal. After the pralines were removed from the mold, the aluminum foil strip was peeled off the pralines and they were then subjected to mechanical testing as described below.
Compression testing of the pralines was conducted using a TAXT-2 texture analyzer (Surrey, England), equipped with a flat plate compression fitment. A single compression test was made using a platen speed of 0.5 mm/sec until a 10% strain (deformation) was experienced. The peak force was recorded as a measure of the strength to failure. Measurements were made of control (untreated) pralines, ones that were induction sealed and samples which had their bottoms removed (using a razor blade).
Comparing the strength of the ‘Control Without Bottoms’ to ‘Control’ shows the importance of the bond between the sides of the praline and its bottom in maintaining the overall strength of the praline. The additional fusion afforded by the induction sealing treatment strengthened the bond between the bottom and the sides, resulting in approximately a 19% improvement in strength over the control.
Number | Date | Country | Kind |
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09155591 | Mar 2009 | EP | regional |
This application claims priority to European Patent Application Number 09155591.2, filed on Mar. 19, 2009. This application also claims the benefit of U.S. Provisional Application No. 61/162,441, filed Mar. 23, 2009.
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Number | Date | Country | |
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20100239725 A1 | Sep 2010 | US |
Number | Date | Country | |
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61162441 | Mar 2009 | US |