NL8002672A - NEW METHOD FOR MANUFACTURING SPARKLING CANDIES. - Google Patents

Description

New method for the production of sparkling sweets.

The invention relates to a new method for the production of sparkling sweets.

Sparkling candies are produced by a known method which exhibits a characteristic sputtering as a result of the release of gas, which is under overpressure in the candies. The sputtering takes place when the candies are consumed.

The key point in imparting this effervescent property to confectionery is the manner in which the gas causing the effervescence is trapped in the molten syrup. 10 According to the known method, a gas is trapped in a mass of molten sugar or mixture of sugars, by means of a special stirrer, which distributes the gas in this mass.

The invention now relates to a new process, which is an improvement and extension of the hitherto known process, and moreover avoids some disadvantages of the known process, which are listed below: 1) The syrup mess has a high viscosity, making it difficult to distribute and trap gas therein. It is not possible to change the size of the gas bubbles, since it is a constant depending on the characteristics of the equipment used.

3) The known method also has the disadvantage that only a part of the high-pressure vessel is filled with each application, because it is necessary to maintain a relatively large empty space above the molten syrup mass.

These are conditions that depend on how gas is included. It means that in the known method it is not possible to make maximum use of a very expensive device such as a high-pressure vessel.

The invention now relates to a method in which a sugar mass is melted in a high-pressure vessel, the molten mass obtained is stirred and a non-toxic gas is added at the same time in the lower part of the high-pressure vessel below the lowest point of the stirrer via a porous plate initiates to a pressure of more than 15 atra is obtained and then the molten mass cools rapidly.

In this new method according to the invention, the entire capacity of the high-pressure vessel is utilized, which reduces the cost of the end product per unit weight, because only a very small amount of empty space in the upper part of the high-pressure vessel. above the melted sugar mass is needed.

By arranging the porous plate in the bottom of the high-pressure vessel, the gas is distributed as a spray into the molten sugar mass over a large number of points, and the gas bubbles formed thereby move over the greatest possible distance in the vessel.

The gas is introduced slowly as possible; the supply point for the gas is always below the lowest point of the stirrer.

While the gas is being introduced, the stirrer is operated to reduce the gas bubbles formed in the molten sugar mass and disperse them throughout the molten sugar mass, which may contain one or more sugars.

The gas can be introduced as long as it is considered desirable, because even when the maximum operating pressure has been reached, it is sufficient to open the needle valve, which is fitted in the top of the high-pressure vessel for this purpose, in order to enable the gas by bubbling the molten sugar mass. Due to the high viscosity of this mass, only the large bubbles reach the surface, while the small bubbles are dispersed in the entire mass.

The gas is introduced into the bottom of the high pressure vessel so that it has the longest possible path and the greatest possible contact with the molten mass, thereby increasing its dispersion and entrapment therein.

The gas inlet into the molten sugar mass (containing one or more sugars) is made through a plate specially designed for this purpose, which is made of an inert and temperature-resistant material. Best results have been obtained using plates made entirely of embedded stamped glass, which contains no binder, and the stamped glass has been pre-cleaned to remove all foreign materials. A porous stainless steel plate is also suitable.

The main feature of this plate is the diameter of the 35 pores, as it allows to control the size of the bubbles. The pore diameter is in the range of 20 µm to 3 mm and the most suitable size is used for a particular application. The best results have been obtained with bubbles with a diameter of 0.3-0.01 mm. When the bubbles are very small and having a diameter of less than 0.01 mm, the sputtering intensity is very low or 800 2 6 72

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The mode of action is expected to proceed as follows:

When the gas is introduced at a slow but constant rate, the bubbles rise to the surface. The larger bubbles 5 rise at a comparatively higher rate through the tough mass and reach the surface before other smaller bubbles, which have been previously introduced, and therefore move with less pressure. When the larger bubbles with a higher pressure reach the surface, they prevent the smaller bubbles from emerging, and the latter are dispersed and enclosed in the molten mass. The effervescent system, for which embedded glass in plates is used, is contained in the bottom of the high pressure vessel and its placement is very simple as it can be removed without the need to open the high pressure vessel, which facilitates the exchange or cleaning of the plate.

Also, as a new phenomenon, the invention includes the fact that the effervescent product has two completely different actions when it comes into contact with water or other suitable solvent or when it is put in the mouth. These consist of a) Sputtering, which takes place occurs when the gas trapped or diffused in the sugar mass is released, which has already been achieved with the prior art process.

b) Explode or break, which occurs when a piece of the confectionery suddenly, but harmlessly, detonates into 25 smaller pieces, which in turn emit the characteristic spluttering caused by gas bubbles with a diameter of more than 0.15 mm, while the sputtering is caused by gas bubbles with a diameter of less than 0.15 mm.

The above-mentioned detonation is a new phenomenon provided by the invention, and is a curious and very important property obtained when gassing the sugar mass. This detonation occurs only at pieces larger than 1.6 mm and this is a special feature of the product according to the invention. It is, of course, clear that the enclosed amount of gas is the smaller the smaller the size of the pieces, since when breaking a piece, part of the enclosed gas is released Best results are obtained with pieces with a diameter of more than 0.5 mm.

It is important to remove the pieces which, because of their small size 800 2 6 72-4, do not exhibit the characteristic sputtering effect, because in the absence of this the quality of the product is impaired.

In order for the product to absorb more bubbles, small amounts of agar agar, carboxymethyl cellulose (CMC) and the like can be added to increase the viscosity.

When the effervescent candy produced according to the invention is dissolved in water or put in the mouth, it causes a splutter caused by the pressurized gas 10 in the mass of the candy being released.

It is very important that the sputtering of the candy has sufficient intensity and continuity to produce a pleasant and pleasant sensation. It is necessary in this context to take into account not only the size of the bubbles, but also the ensure that the film around each bubble is strong enough to hold the gas at the pressure with which it was trapped in the syrup during the manufacturing process. Such pressurized bubbles should only be released when water or a suitable solvent or when the candy is taken in the mouth for consumption.

As sugar or sugar mixture, any sugars or sugar products which are solid at room temperature and which are liquid at elevated temperature or form a sticky mass can be used. monosaccharides, such as ribose, xylose, arabinose, glucose, galactose, laevulose, mannose, fructose or disaccharides, e.g. sucrose, maltose, lactose, raffinose, or trisaccharides or tetrasaccharides, sorbitol, gluconic acid, glucuronic acid, and derivatives such as methyl glucose, methyl arabinose, ethyl glucose, propyl glucose and benzyl glucose.

As the gas, it is possible to use the non-toxic gas, but preferably helium, air, oxygen, nitrogen or carbon dioxide is used.

Before fumigating the sugar syrup, other products may be added to preserve it, as well as flavors, colorings, buffers, thickeners, fatty acids and oils, and any substance may be added to improve appearance or to improve organoleptic properties and characteristics. improve.

The examples below serve to illustrate the invention, but do not limit the invention.

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Example I

A high-pressure vessel made of 18/8 stainless steel with a volume of 100 l that can withstand a pressure of 250 atm, is equipped with a filling opening, stirrer, three safety valves, heating, a peephole, a 5 opposite peephole, a needle valve in the top , a pressure gauge, an outlet valve in the bottom and a gas spray inlet through a plate with 0.4 mm pores.

The high pressure vessel is filled with a molten mass of 10 kg of sucrose, 30 kg of glucose, 20 kg of lactose and enough water to melt the mixture properly.

Then a very slow flow of carbon dioxide is introduced into the mixture while the stirrer is kept in motion. Once the carbon dioxide has expelled all the air from the high pressure vessel, all valves are closed and the pressure is gradually increased to 50 atm. generally at a rate of 1 atra / min.

When the pressure has reached 50 atm, the stirring is stopped and the mass is cooled as quickly as possible by means of a cooling system, in which the coolant is kept at a temperature below 0 ° C. As a result, the confectionery is minimized as hygroscopically, by avoiding possible hydrolysis.

The product obtained contains 3 ml / g of gas, which is contained in gas bubbles of various sizes.

Example II

25 A 500 L stainless steel high pressure vessel that can withstand very high pressure is equipped with a filling port, a stirrer, two safety valves, a pressure gauge, two needle valves and a gas inlet in the form of a plate with pores of 0.5 mm, through which the gas is sprayed.

The high pressure vessel is filled with a molten mass of 50 kg of sucrose, 50 kg of lactose and 50 kg of glucose and enough water to allow the mixture to melt properly.

Once the mixture has melted well, carbon dioxide is introduced into the high-pressure vessel until a pressure of 75 atm is reached. The stirrer built into the high-pressure vessel is turned on and gas is vented through the needle valve in the top of the high-pressure vessel. carbon dioxide is introduced through the bottom of the high pressure vessel. This entry point is located below the lowest point of the stirrer. This will introduce gas bubbles into the sugar mass, which will be dispersed in the mass by the stirrer.

In this way it is possible to gas the molten sugar mass with the desired amount (ml / g) of gas.

The average size of the gas bubbles is 0.08 mm, but there are also larger ones of almost 0.2 mm and the first ones give a kind of explosion before sputtering.

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Claims (10)

1, New method for the production of sparkling confectionery, characterized in that a sugar mass is melted in a high-pressure vessel, the molten mass obtained is stirred and a non-toxic gas is substantially simultaneously passed through a high-pressure vessel in the bottom part of the high-pressure vessel below the lowest the porous plate placed on the stirrer leads to a pressure of more than 15 atm and then the molten mass cools rapidly, 2. Method according to claim 1, characterized in that the pressure rise in the high-pressure vessel is maintained in the range of 0.1-5 10 atm / min, Method according to claim 2, characterized in that a pressure rise of 1 atra / min is maintained in the high-pressure vessel, Method according to one or more of the preceding claims, characterized in that a porous plate with 15 pores with a diameter of 20 µm to 3 mm is used. Method according to one or more of the preceding claims, characterized in that a porous plate of inert material is used, 6. Process according to claim 5, characterized in that a porous plate of porous stainless steel is used. Method according to one or more of the preceding claims, characterized in that a needle valve is opened in the upper part of the high-pressure vessel during gassing. 8. Method according to one or more of the preceding claims, characterized in that the pressure in the high-pressure vessel is brought to 35-50 atm. 9. Method according to one or more of the preceding claims, characterized in that gas bubbles of a non-toxic gas are formed in the sugar mass, some of which have a diameter of more than 0.15 mm. 10, A method of manufacturing effervescent candies as described herein. sseassssseess 800 2 6 72