• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    The invention is in the field of vacuum packaging of foodstuffs. It relates to a method, a system of devices for the continuous sterilization or pasteurization of the foodstuffs contained in specific rigid containers, followed by the continuous deep vacuum sealing of said containers, evacuation obtained by rotary injection of steam between the lids and the containers followed by a closing of the containers and a cold shower bringing the condensation of the steam inside the container and consequently a deep vacuum, for a deep vacuum preservation of the food in exceptional organoleptic and nutritive quality conditions, thanks to a drastic reduction in the cooling times of the containers after sterilization or pasteurization, reduction of time obtained by boiling under vacuum at low temperature, boiling distributed homogeneously throughout the container. It is particularly suitable for pasty or liquid products or pieces included in a liquid or pasty device. It imposes the use of an exceptionally rigid container, intended to be closed under a deep vacuum and whose closure is effected by a lid free of attachment means and provided with an elastic seal, lid held only by the vacuum and which can be opened by an empty case system.
    公开号:FR3046527A1
    申请号:FR1650122
    申请日:2016-01-07
    公开日:2017-07-14
    发明作者:Jean Larroche;Brigitte Larroche
    申请人:SODETECH;
    IPC主号:
    专利说明:

    CONTINUOUS PROCESS. AND SYSTEM FOR PASTEURIZATION OR STERILIZATION OF FOODSTUFFS IN A CONTAINER
    RIGID FOLLOWED BY ITS DEEP VACUUM CLOSURE BY INJECTION OF ROTARY STEAM AND RAPID COOLING
    HOMOGENEOUS
    Field of the invention
    The present invention relates to the field of food processing, and more particularly to the packaging of foodstuffs in rigid containers.
    The present invention more particularly relates to a method and a system for the continuous sterilization or pasteurization of the foodstuffs followed by the continuous deep vacuum sealing of said container for a deep vacuum preservation of food under conditions of exceptional organoleptic and nutritional quality , thanks to a drastic reduction in the cooling times of containers after sterilization. It implements the use of a particular container, intended to be closed under a deep vacuum. It is suitable for pasty or liquid products or pieces included in a liquid or pasty device.
    In the rest of this document, it is appropriate to denote by "container" the assembly formed by a "container" and its "lid".
    State of the art
    Historically important, canning practices are gradually replaced partly by freezing, in connection with the organoleptic and nutritional disadvantages of over-cooking born from the fact that canning can not be cooled quickly enough after sterilization. Progress has nevertheless been made with the metal vacuum packaging, certainly with limited vacuum levels.
    US Patent No. 1,931,911 discloses a method of vacuum packaging food products in a container closed by a lid without attachment means. This process is unsuitable for continuous serial production.
    French Patent No. FR 2,385,607 describes a method in which steam is injected between the lid and the container, then the closed container is introduced into an autoclave placed under pressure by injection of compressed air during pasteurization or sterilization, to be after gradually cooled and reset to atmospheric pressure. Alas, the mixture of air and steam being heterogeneous, the temperature in the autoclave is also heterogeneous. On the other hand, this method does not allow enough oxygen to evacuate the container. Finally, the sterilization time required to obtain the safety of preservation necessarily leads to excessive cooking of the product aggravated by the too slow cooling recommended by the text and which would lead to degradation of the product caramelization of sugars and / or degradation of tastes and of color by the reaction of Maillard.
    French Patent No. FR 2 686 059 uses the same methods and means as the patent mentioned in the preceding paragraph, and is subject to the same impossibilities and disadvantages.
    European Patent No. EP 79101660 (SCHWERDTEL) proposes an installation for the vacuum closure of boxes with a lid which comprises a first step of blocking the lid on the outlet of the box by the vacuum obtained in an enclosure and a second stage, in another enclosure, crimping the lid. However, EP79101660 (SCHWERDTEL) does not discuss the use of the deep vacuum in the conservation process and is interested in the reinjection of gas.
    Also known is the patent No. EP 2 106 219 which describes a packaging system and method which incorporates the elements of a previous patent EP0715587 and allows the vacuum packaging of aqueous food products in a rigid container sealed by a flexible cover. The container is heated in a partial vacuum to bring the liquid to a boil so that the generated vapor expels the other gases from the container through the unsealed opening, and the container is sealed. Unfortunately, given the chaotic release of gases, there is still a little air and the deep vacuum is not reached, the best proof being that this process does not require a very rigid container, as clearly stated in the version of previous patent EP0715587.
    French Patent No. FR 2,829,106, by the inventors of the present invention, actually makes it possible to achieve a deep vacuum and applies to very large vacuum-resistant containers, such as the containers described by the same inventors in the patent. However, the process described requires the containers to be passed through a sterilization or pasteurization phase after evacuation.
    European Patent No. EP 2226252 discloses a process for continuous vacuum packaging of pasteurized and / or sterilized food products. However, this European patent remains imprecise on the level of vacuum reached since it states exactly that the vacuum level reached must not exceed 950 mbar throughout the process and does not specify how one can reach or if one can reach such a level vacuum, or how to ensure sterile transfer between food preparation equipment and casing.
    Finally, European Patent No. EP 2,357,136 describes a steam injection head and cold water for the realization of continuous vacuum packaging of food products that can be sterilized or pasteurized in a rigid container such as that described in the patent EP 2 226 252. EP 2 357 136 also describes a method of using said head in which the container receives a prepared product ready for consumption, previously degassed, pasteurized or sterilized at high temperature.
    Unfortunately, the steam jets proposed in EP 2 357 136 are disordered and fail to remove all the air from the required areas, the patent EP 2,357,136 mentioning a relative vacuum close to 850 mbar, which represents 100 mbar less than the performance proposed by the present invention, ie a lowering of the boiling point in the closed container under deep vacuum from 55 ° C. to 37 ° C., ie a considerable increase in the boiling range, thus of rapid cooling. product related to the latent heat of evaporation / condensation of water. Patent EP 2,357,136 also does not specify how sterile transfer can be guaranteed between the food preparation apparatus and the casing.
    By improving the inventions subject of the European patents EP 2,226,252 and EP 2,357,136, the same inventors propose means which solve the problems stated above by improving the degassing of the products and thus the vacuum level to shorten the total cooking time. and propose on the other hand means to ensure the sterility of the products throughout the process, and to obtain a rapid and homogeneous cooling.
    None of the aforementioned patents allows for a deep vacuum closure after pasteurization or sterilization, which has the effect of adding to the initial cooking of the cooked dishes a second rather destructive cooking followed by a too long cooling during which the cooking continues until the temperature has fallen back down to 68 ° C in the heart of the product, which makes it impossible to package certain pasty products beyond small capacities, such as purees and in particular fragile vegetable purees which, after sterilization in an autoclave, undergo a caramelization at the center of the boxes, even a browning and a destruction of the vitamins and the aromas contained in the products.
    Deep vacuum is defined here as an absolute partial pressure level of oxygen of at most 10 mbar inside the container measured at 4 ° C. To guarantee this level of vacuum after three years, it is essential that the initial evacuation be done gradually to avoid the cells burst in the food and allows to reach 5mbar of absolute partial pressure of oxygen at the same time. inside the container at the end of the process, measured at room temperature.
    The heating and cooling times of conditioned foods can be considerably shortened by using the heat transfer allowed by the latent heat of vaporization / condensation of water, which represents 2269 kJoule per gram of vaporized or condensed water, ie 542 kcal per gram. evaporated or condensed water.
    Statement of the invention
    The present invention relates to a method, a system of devices and novel devices for the sterilization or pasteurization of foodstuffs followed by the vacuum and the deep vacuum closure of said container for a durable vacuum storage of food in exceptional organoleptic and nutritional quality conditions. It implements the use of a particular container, intended to be closed under a deep vacuum without any other means of fixing the lid to the container than the vacuum such as those presented in patent EP2502685 - "Method of forming the wall of the container. 'mouth of a metal container or packaging, device therefor and packaging or container obtained. These containers have an elastic seal at the periphery of the lid on its underside.
    It is suitable for pasty or liquid products or pieces included in a liquid or pasty composition.
    The present invention, by mobilizing various indispensable existing materials and introducing device modifications, device combinations and novel operations, allows for a long-lasting preservation of deep vacuum foods in a rigid container by attaining an absolute pressure of less than 24mbar at least immediately after canning and cooling to 4 ° C, which represents a lowering of the boiling point of the water to 26 ° C in the container and thus an extension of the range in which the benefits of the change can be realized phase and latent heat of water (2269 kJoule / g or 542 kcal / g at boiling), the latent heat remaining relatively constant in the pressure range considered, an extension of the protection period of oxygen products with a guarantee that there remains a residual absolute oxygen partial pressure less than 10mbar at the end 3 years, the usual maximum storage time for canned goods.
    The present invention proposes in its generality to increase the level of vacuum in the container and exploit this deep vacuum not only to cause very rapid cooling of food after closure, but also to better preserve food, and finally to improve the maintaining the lid at its outlet.
    These modalities include providing an initial differential pressure between the interior of the container and the atmospheric pressure, at least of the order of 980 mbar, when the atmospheric pressure is 1014mbar, by suddenly putting the container under vacuum by steam injection overheated, hermetic seal, then cold shower applied to a sterile filled container beforehand.
    With the method which is the subject of the invention, a better preservation of the food substances of their elements, such as vitamins, flavors and fats, which do not have to undergo the alteration of the residual oxygen usually contained in products packaged by prior techniques.
    This method makes it possible, on liquid products, pasty or in pieces with sauce, in particular cooked dishes, to considerably reduce the cooling time after closure, thanks to the fact that all the heat exchanges take place in saturation vapor pressure, and that we therefore take advantage of changes in the liquid / vapor phase (latent heat of vaporization / condensation of water = 2269 kJoule / g 542 kcal / g) which accelerate the heat transfer between the food, the walls of the box and autoclave sterilization. For this purpose, the present invention relates, in its most general sense, to a process for the continuous pasteurization or sterilization under deep vacuum, of food products, in a rigid container, the closure of the container portion of said container in front of the container. performed by a metal cover free of attachment means and provided with an elastic seal which provides a connection between the container and the lid with vacuum, comprising the following steps: »degassing of the product ready to be packaged; • Pasteurization or sterilization of the product; • Cooling of the product to reach the filling temperature; • Initial sterilization and degassing of the containers, then transfer of said containers under a first chamber, without breaking sterility or introduction of incondensable gases; • A step during which the product is brought, dosed and filled into the containers under a first chamber maintained in a superheated steam atmosphere, the filling ceasing when reaching the last centimeter of the container, so as to leave a suitable space , of a volume sufficient for the time to come and under certain conditions, the condensation of the superheated vapor allows to obtain the objective vacuum; • Outlet of the container filled with food and steam of said first chamber and inlet of said container filled with food and steam under a second insulated chamber, also maintained in a superheated steam atmosphere where the container is positioned in expectation of fate lid; • A step during which the lids from a tubular distribution tray, after having been previously disinfected or disinfected during distribution, are separated and, after their seal has eventually been softened, are introduced into the second enclosure and each deposited on a container filled with food, said covers crossing on their way a stream of superheated steam exiting the second chamber to the lids dispenser store; • A step in which each lid is lifted from its container to inject superheated steam between them; A step in which the container and the lid are pressed against each other to bring the soft seal of the lid into contact with the rounded edge of the mouth of the container, this closure being used to completely isolate the container; outside a space named here "vacuum chamber"; • Stopping the steam injection and cold water shower of the lid of the container to cool and ensure the condensation of the vapor located in the vacuum chamber, which then causes a vacuum in the container relative to the atmospheric pressure, sufficient vacuum to ensure that the container and lid are securely joined; and • Evacuation of the vacuum container to a cooling tunnel where the cooling continues until the temperature has reached room temperature, the cold shower must continue as long as the temperature in the product has not decreased in below the cooking temperature of food at 68 ° C.
    Preferably, said method further comprises a step of injecting superheated steam into the empty containers before filling to further improve the degassing by avoiding the imprisonment of air bubbles beneath the pasty products during their filling.
    Advantageously, said method comprises several steps consisting in eliminating all possible sources of incondensable gas, from the preparation of the product to the closure of the container, including at the time of filling of the containers, so as to guarantee in the long term a deep vacuum in the said container.
    According to one embodiment, the sterilization and degassing provided at the time of sterilization of the containers, the filling of the container and its closure are by injecting superheated steam to over 130 ° C by imposing a rotary motion of the steam in the spaces concerned, vortex or vortex type, capable of removing all traces of air in a very limited time and replace it exclusively with superheated steam capable, during its cooling and condensation, cause the setting of the container under said deep vacuum, the steam being injected at a temperature, a rate and for a time adapted to allow sterilization of the areas concerned.
    Advantageously, the sterilization and initial degassing of the containers are done by presentation of the containers, opening at the bottom, and injection of superheated steam into the interior of the container, the operation then having to take place in the open air so that the air can escape from the container and the superheated vapor, lighter than air, remains trapped in the container In this case, a reversal operation of the container takes place prior to its filling, this reversal to be done in the enclosure Isolated maintained in slight overpressure of superheated steam.
    According to one embodiment, said method comprises a step of continuously creating in the conditioned containers the thermodynamic conditions necessary for all the heat exchanges in the container to take place at the boiling point and of the condensation, making it possible to exploit the heat latent vaporization of water to evacuate the heat of the container.
    Advantageously, said method implements a homogeneous boiling of the product, said boiling being normal for the materials containing water and placed under the envisaged vacuum, which makes it possible to continuously impose a homogeneous cooling of the food in the already closed containers. .
    The present invention also relates to a system for continuous pasteurization or continuous vacuum sterilization of food products, comprising: • means for degassing the bulk product, these means being either a vacuum system or a cooking system that naturally induces degassing, ie cooking under vacuum; • means of sterilization and initial degassing of the containers; Means for sterilizing and cooling the bulk product, said cooling means being placed at the outlet of said sterilization means; Means for separating and disinfecting the lids, using the superheated steam as a means of disinfection, this vapor inducing a degassing of the environment of the lid, which contributes to the degassing of the entire system, and any necessary softening of the seals lids; • Filling means possibly allowing the evacuation of the incondensable gases in the container, and in any case allowing the dosage and sterile filling of the food in the container, said filling means can be installed in series on a filling line; • means allowing both the manipulation of the lids, the injection of steam, the closure of the containers filled with food and the cooling of the containers by cold shower, means also called "closing head"; A first enclosure, located upstream of the entire vacuum closure system and including means for positioning the containers and a filling line, said enclosure to be maintained in optimal sterility by the initial injection of steam overheated from the beginning of the process, then kept under steam by a slight vapor overpressure that imposes a current exiting the enclosure to the free atmosphere, all of which require the installation of flexible skirts at the entrance of the enclosure to avoid the air passage; A second chamber also placed under slight pressure of steam under the same conditions, this enclosure including the entire sector of exchange of lids and containers filled between first, second and third and fourth carousels, the steam escaping from the said second enclosure only by the entry of the lids at the tubular store and by entering the first carousel and the exit of the fourth, all this requiring the installation of flexible skirts at the entrance and exit of said second enclosure to avoid the passage of air, and to connect said second enclosure to said first enclosure hermetically without the possibility of air entry, • means for transferring the containers between the other means that ensure the maintenance of the degassing and the sterile condition of products and containers; • means of braking the air intake in the enclosures under superheated steam.
    Brief description of the drawings
    The invention will be better understood by means of the description, given below for purely explanatory purposes, of an embodiment of the invention, with reference to the figures in which: FIG. 1 shows the entire system devices necessary for carrying out the present invention; Figure 2 is a schematic view of the installation of carousels of the device system implementing the sequence of closing operations of the container according to the invention; FIG. 3 represents a schematic view of the "filling head", with the symbolic representation of the vortex or vortex of vapor induced by its operation; Figure 4 is a schematic view of the "closure head" which allows the introduction of the lids on the container, their closure after rotary injection of steam, the cold shower containers and their cooling; Figures 5 and 7 show axial sections of the filling head shown in Figure 3, with, respectively, the configuration with induced vortex or vortex vapor and the movement of food; Figures 6 and 8 show axial sections of the closure head shown in Figure 4, in two angularly offset section planes; • Figures SF and 11 show a section and a diagram of the mandrel of the filling head shown in Figure 3. • Figures 10 and 12 show a section of the mandrel of the closure head shown in Figure 4, respectively in the high and low position . • Figure 13 shows the flow of steam through the filling head mandrel shown in Figure 3. • Figure 14 shows the annular ring of the closure head shown in Figure 4. • Figure 15 shows the flow of the filling head. steam and chilled water in the chuck of the closure head shown in Figure 4.
    Detailed description of embodiments of the invention
    The necessary devices (shown in FIG. 1) for implementing the present invention are the following: a first device 20 (FIG. 1) for degassing the products, this device being for example a vacuum system or a system cooking naturally inducing degassing; A device 21 (FIG. 1) for sterilizing, degassing and positioning the containers, this device using, for example, hydrogen peroxide, superheated steam or UV rays, said device terminating without any break in sterility or return of air inside the containers to a transfer chain, possibly able to return the containers if they were introduced upside down, said transfer chain entering an isolated chamber 29, contiguous to another enclosure 28 where carry out part of the operations; A device 22 (FIG. 1) for sterilizing or pasteurizing food. This device is composed of an ohmic tube or a heating tube with scraped surfaces, the latter such as those used in the tomato concentrate industry for all products to be pasteurized, or any other system that would have allowed to sterilize or pasteurize the product, all these systems necessarily being under pressure, the advantage of the ohmic tube being that it reduces the cooking time during heating of the product while optimizing the sterilization time; A cooling device 33 (FIG. 1) at the sterilization outlet only, intended to bring the product to the correct filling temperature as quickly as possible, namely between 70 and 98 ° C. without losing its sterility, this device being able to be a multitube system immersed in a bath or under a cooling shower placed in a pressure-controlled enclosure; • a filling head 23 (FIG 1) optionally to complete the degassing and sterilization of the container, but above all allowing the dosage and sterile filling of food in the container from the device 22 connected by a sterile piping system. The "filling head" is also shown in FIG. 3 in a form intended for hot aseptic filling, inducing a particular movement of vortex or vortex vapor jets, the only way of overcoming the residual air in the space concerned, and comprising a product distribution circuit and a filling spout. The filling head 23 is installed in series on a filling line 32; A carousel device 1,2,3 (FIG. 1 and FIG. 2), the first carousel 1 making it possible to clock the delivery of the filled containers onto the third carousel 3 while the second carousel 2 makes it possible to time the delivery of the covers to the third carousel carousel 3; A device 24 (FIG. 1) for introducing, separating and disinfecting the covers 9 (FIG. 2) connected in series by the carousel 2 (FIG. 1 and FIG. 2) and fed by a tubular magazine, this magazine being placed made in a vapor stream leaving the enclosure 29; • a device 25 (FIG 2) for transferring containers filled with food from the first carousel 1 (FIG 1 and FIG 2) to the third carousel 3 (FIG 1 and FIG 2); A device 26 (FIG. 2) for transferring the lids of the carousel 2 (FIG. 1 and FIG. 2) to the carousel 3 (FIG. 1 and FIG. 2); A closing head 27 (FIG. 1 and FIG. 2) allowing both the manipulation of the covers, the injection of rotating steam, the closing of the containers filled with food and the cooling of the containers by a cold shower, also represented in FIG. 4 in detail, said device being carried in series by a third carousel 3 (FIG 1 and FIG 2), said closing head 27 comprising a mandrel 8 (FIG 4) carrying magnetic means 10 (FIG 4), said head of FIG. closure further comprising means for inducing a particular movement of vortex or vortex vapor jets, in order to overcome the residual air in the space concerned; A carousel 4 (FIG 1 and FIG 2) for evacuating the containers finally closed to a cooling zone 31 (FIG 1 and FIG 2). An enclosure 28 (FIG. 1 and FIG. 2) maintained in an optimal state of sterility by the initial injection of superheated steam at the start of the process and then kept under steam, all by any appropriate steam injection means, this enclosure including all the sector for exchange of lids and containers filled between the carousels 1, 2, 3, 4 (FIG 1 and FIG 2), the steam escaping only in height through the entrance of the covers at the tubular store of the device 24 and the entrance and exit located in the vicinity of the carousels 1 and 4 (FIG 1 and 2), these carousels 1 and 4 being fully included in the enclosure 28, flexible skirts placed at the entrance and exit enclosure 28 limiting the passage of air; An enclosure 29 (FIG. 1 and FIG. 2) situated upstream of the entire vacuum closure system and including the transfer chain and the filling line 32, and therefore situated just before the containers enter the enclosure 28, and it being connected in a hermetic manner, said enclosure 29 undergoing at the beginning of the process a stream of steam leaving the enclosure 28 to purge it of its air, then being put also under slight pressure of superheated vapor thus leaving towards the free atmosphere at the device 21, flexible skirts at the inlet of the chamber 29 limiting the passage of air;
    Figure 3 shows in detail the "filler head" 23 (FIG 1 and FIG 2) which allows both possible additional degassing and disinfection of containers and sterile filling of the containers with sterilized or pasteurized food.
    FIG. 4 shows in detail the "closing head" 27 (FIG. 1 and FIG. 2) which allows both the placing of the lids on the container, their closure after rotary injection of steam and the showering of the containers. with cold water that induces condensation in the container and the installation of an internal relative vacuum that ensures the holding of the lid on the container. The filling head is characterized by a particular orientation of the steam injection nozzles which creates a vortex or vortex movement of steam in the container, a movement which ensures the complete evacuation of the residual air. With the aid of these schemes, the complete process which characterizes the present invention and which proceeds continuously in the following steps as described in FIGS. 1 and 2 can be better understood: (a) The product is prepared in its state sterile final and it is degassed, either in a separate cooking operation, possibly under vacuum, or after cooking, continuously in a tubular installation with worm connected in series then to the pasteurization or sterilization system, or at the same time it is brought to temperature in a sterilization or pasteurization installation which can be either a scraped surface heating tube or an ohmic tube, or any other method which would bring the product to be conditioned to the correct filling temperature in a state degassed and cooked to point, said degassing being necessary to further increase the level of vacuum at the end of the process, the filling temperature may be 90-92 ° C for pasteurized products, which does not always require cooling, and below 98 ° C for products already sterilized, the cooling between the sterilization outlet at 121 ° C and the temperature cb filling to be done as quickly as possible to advance the end of the cooking of the product, said cooling may be complete for a cold or partial aseptic filling for hot aseptic filling; (b) A first sterilization of the containers must take place prior to loading them on the filling line 32 (FIG. 1), either with hydrogen peroxide, superheated steam or UV rays or a combination thereof, followed by a compulsory degassing, the latter to be done by injecting superheated steam to more than 130 ° C in the containers, this exposure to superheated steam taking place in the open air, so that the air contained in the containers can escape outside the packaging system, and said containers being presented opening downwards, so that steam, lighter than air, tends to remain in the container, (c) the empty containers then enter , full of steam and opening downwards, in the chamber 29 (FIG 1) placed under superheated steam, by a transfer chain on which they are then returned, opening upwards, then brought s to the filling line 32 (FIG. 1) where they pass into the zone CC'-DD 'where a "filling head" 23 (FIG. 1 and FIG. 3, FIG. 5, FIG. 7) then lowers on each container vacuum that arrives so as to leave a free space between said head 23 and the mouth of the container of about 5 to 10 mm and it is then that superheated steam, for example at 120-135 ° C, can optionally and in addition, to be injected inside the container by the injection device of the "filling head" 23, the injection being rotated tangentially to the walls of the empty container and at an angle, creating a vortex or vortex of powerful saturated vapor which ensures a complete elimination of any residual air in the container, which is a solution to avoid possible entrapment of air pockets in the product thereafter; (d) by the "filling head" 23 (FIG. 1), the product is then dosed in the containers 11 (FIG. 1) on the filling line 32 (FIG. 1) situated under the enclosure 29 (FIG. 1), (e) in the case of packaging pasteurized products, the product, which is already at the filling temperature, induces an additional pasteurization of the container at 90 ° C-92 ° C; (f) the filling ceases when one reaches about the last centimeter of the container, so as to leave at the head of the container a sufficient space without product, called "vacuum chamber" (FIG. 12), representing about 10% of the height of the container, to accommodate a sufficient amount of steam to subsequently ensure sufficient condensation and a deep vacuum; (g) the container filled with food and steam and thus completely free of air, then leaves the chamber 29 and enters the enclosure 28 (FIG 1) by a transfer chain on the carousel 1 (FIG 1 and FIG 2); (h) then said filled container is transferred from the carousel 1 to the carousel 3 (FIG. 2) by a transfer mechanism 25 (FIG. 2) which brings it to a deposition base centered vertically under a closing head 27 (FIG. 2 and FIG 4, FIG 6, FIG 8); (i) while the preceding tasks are taking place simultaneously, the covers 9 (FIG. 2) issuing from a tubular distribution magazine 24 (FIG. 2), after having been previously disinfected or disinfected during distribution, are separated and distributed; to one on the second carousel 2 (FIG 2) so that enter the enclosure 28 (FIG 1) only disinfected lids and the gum seal may have been eventually softened by steam as needed ; (j) the carousel 2 returns one by one the lids 9 to the carousel 3 (FIG 2) by a transfer mechanism 26 (FIG 2), this occurring under the sterile enclosure 28 in superheated steam medium and each of these lids is placed on a container filled with food; (k) above each container covered with its cover is therefore a closure head 27 (FIG 2 and FIG 4, FIG 6, FIG 8) in the raised position and may still contain traces of air which then undergoes degassing complete by superheated steam jet, and this thanks to integrated steam circuits in said head 27, which open at the lower part of said closure head 27; (l) the container filled with food and provided with its metal lid, which circulates at this time on the carousel 3 (FIG 2) in the chamber 28, is then pushed upwards by a piston and its neck is introduced into the bell forming the closing head 27 (FIG 4), which, under the action of its magnetic means 10 (FIG 4), lifts the cover which is then positioned on the mandrel 8 (FIG 4), leaving between the cover and the edge of the container a space of 5 to 10 mm in height; (m) at the passage of the container in the zone AA'-BB 'of the carousel 3 (FIG. 2), a superheated steam at 125 ° C. is then injected between the lid and the mouth of the filled container, thanks to the steam injecting nozzles distributed around the lower part of the closure head 27 (FIG 2 and FIG 4, FIG 6, FIG 8), so as to create a vortex or vortex superheated steam (FIG 14) which ensures a complete elimination of gases present between the lid and the product in the container and their replacement by superheated steam, (n) after the steam injection by the closure head 27 (FIG 2 and FIG 4, FIG 6, FIG 8), the container 11 and the lid are pressed against each other by a piston, this putting in contact the flexible seal 14 (FIG 12) of the lid 9 with the rounded edge of the mouth of the container 11, this closure allowing to isolate completely the "vacuum chamber" 5 (FIG. 14) from the outside; (o) by the same piston movement are caused the stopping of the steam injection and the opening by the valve 49 (FIG 6) of the cold water circuit present in the closure head 27, (p) the head closure 27 (FIG 2) being supplied with cold water, this water flows on the mandrel 8 (FIG 4) which carries the magnetic means which hold the cover 9, which mandrel is provided with at least one inlet port water 12 (FIG 4) and at least one lateral water outlet port 13 (FIG 4), which floods the cover 9 (FIG 14) with cold water and perform a first cooling which ensures the condensation of the vapor situated in the vacuum chamber 5 (FIG. 14), which then causes a partial depression in the container with respect to the atmospheric pressure, sufficient depression to guarantee that the container and the lid are securely joined; (q) it is only then that the closed container can possibly leave the enclosure 28 (FIG. 1) and cooling with a cold shower is continued on the cover 9 (FIG. 14), the depression caused is sufficient to cause uniform boiling throughout the product, boiling which causes a very rapid and uniform cooling throughout the product, the vapor emitted by the boiling said condensing on the lid cooled by the cold shower, which allows to evacuate the container 2269 kJoule per gram evaporated / condensed water or 542 kcal per gram of evaporated / condensed water; (r) the vacuum container is then discharged to a cooling tunnel 31 (FIG. 1) by the carousel 4 (FIG. 1 and FIG. 2) where the same boiling and condensation phenomenon continues until the temperature has reached room temperature, the cold shower must continue as long as the temperature in the product has not dropped below the cooking temperature of food at 68 ° C, this temperature drop being homogeneous in the product and occurring at least 3 times faster than in a conventional container without deep vacuum, for the 5kg format, when the product has been properly degassed at the beginning, and at least 6 times faster, for the case of the 1.3kg tambourine format .
    The method according to the invention can also be used to package in sterile containers a super clean product prepared from sterile ingredients and intended for distribution by the cold chain without pasteurization or sterilization, with cold aseptic filling, provided that the product withstands superheated steam on the surface. In this case, the vacuum reached depends on the initial degassing and steam injection conditions and can not rely on the cooling of the product itself to further increase the final vacuum. It is therefore necessary to increase the size of the vacuum chamber 5 (FIG. 12) to make the condensation more important and to reinforce the degassing and steam injection operations throughout the process without harming the product.
    In the case of sterile products packaged cold, it was found that the colder the product in the container, the higher the steam flow should be.
    After their closure and partial cooling by the closing head 27 (FIG. 1), the filled pots or boxes, now closed by a hermetic lid, are then evacuated by the carousel 4 (FIG. 1) and then advance in a tunnel of cooling 31 (FIG. 1). This cooling causes additional condensation in the closed container and a rapid increase of the vacuum homogeneously in the container. This drop in homogeneous pressure causes a homogeneous boiling of the product at low temperature, the product cooling very rapidly because of this boiling which consumes 542 kcal / g of evaporated water contained in the product. The steam released by this boiling makes the head space pressure slightly increase again, but the said vapor condenses immediately again by contact with the lid on which the cooling water of the tunnel flows, which recreates inexorably no more emptiness.
    The temperature drop in the container is much faster than heat conduction, a conventional process used in the industry, which reduces the cooling time by 3 to 10 times compared to conventional packaging, according to the invention. size of the containers, with homogeneous temperature drop in the container, for example from 95 ° C. to 68 ° C. in 4 minutes in a 1.3 kg tambourine when the vacuum is correctly made, which makes it possible to stop cooking, unlike conventional cooling processes that leave the center of the containers warmer and induce the caramelization of certain products.
    After sufficient cooling, the pots or cans can pass through a drying tunnel provided that the temperature of the air blown and the duration of exposure to this temperature does not cause a warming of the product and boiling at low temperature in the container . They are then ready for grouping and over-conditioning. The invention presented improves the performance of the methods and system of the prior art, as follows: • By adding a prior degassing phase of the product; • By creating vortices or vortices of steam for the first time during sterilization of containers, a second time in the container just before filling and a third time just before closing the containers in the space between the lid and the product. mouth of the container, these vortices or eddies being allowed by a new orientation of the beaks downwards and tangentially with respect to the wall of the container, which creates pairs of forces able to promote the rotary descent of the steam in the spaces considered the total rotary exhaust of the air outside the container, contrary to all the methods in force in the food industries which only obtain a chaotic displacement of the air and thus a partial degassing. • By fully describing the device systems to achieve new performance in terms of ultimate vacuum in the container. • Reducing heating and cooling times to minimize cooking times without compromising the sterility of the term products.
    It is these first improvements which make it possible to gain about 30 to 100 mbar of vacuum after cooling and to lower the boiling temperature in the container from 10 ° C. to 20 ° C., with the result that cooling is further accelerated for a better quality. improved product, especially for all products containing fats sensitive to rancidity, which finally makes possible the packaging of purees in containers of collective size (3 kg).
    In addition, the present invention adds to the above patent a device system that allows the sterile transfer between the sterilization / pasteurization means and the casing, transfer that was not fully addressed in the previous patents.
    权利要求:
    Claims (7)
    [1" id="c-fr-0001]
    1. Process for the continuous pasteurization or sterilization under deep vacuum of food products, in a rigid container, the closing of the container portion of said container to be carried out by a metal cover free of attachment means and provided with an elastic seal ensuring a connection between the container and the lid thanks to the vacuum, characterized in that it comprises the following steps: • degassing of the product ready to be packaged; • Pasteurization or sterilization of the product; • Cooling of the product to reach the filling temperature; • Sterilization and degassing of the containers, an injection of superheated steam at more than 130 ° C taking place in each container, then transfer of said containers under a first enclosure, without rupture of sterility or introduction of incondensable gases, • A step during which the product is brought, metered and filled into the containers under said enclosure, the filling ceasing when one reaches about the last centimeter of the container, so as to leave a suitable space, of a volume sufficient for that the moment comes and in certain conditions, the condensation of the superheated steam allows to obtain the objective vacuum; • Outlet of the container filled with food and steam from said first chamber and inlet of said container filled with food and steam under a second insulated chamber, also maintained in superheated steam atmosphere where the container is positioned in expectation of its lid; • A step in which the lids from a tubular distribution tray, after having been previously disinfected or disinfected during distribution, are separated, dispensed, introduced into the second chamber and each placed on a container filled with food , said covers crossing on their way a stream of superheated steam exiting the second enclosure to the lids dispenser store; • A step in which each lid is lifted from its container to inject superheated steam between them; A step in which the container and the lid are pressed against each other to bring the soft seal of the lid into contact with the rounded edge of the mouth of the container, this closure being used to completely isolate the container; outside a space named here "vacuum chamber"; • Stopping the steam injection and cold water shower on the lid of the container to cool and ensure the condensation of the vapor in the vacuum chamber, which then causes a vacuum in the container relative to the atmospheric pressure sufficient vacuum to ensure that the container and lid are securely joined; and • Evacuation of the vacuum container to a cooling tunnel where the cooling continues, the cold shower to continue as long as the temperature in the product has not dropped below the cooking temperature of foods to 68 ° C
    [2" id="c-fr-0002]
    2. Method according to claim 1, characterized in that it further comprises a step of injecting superheated steam into the empty containers before filling to prevent the imprisonment of air bubbles below the pasty products at their disposal. filling.
    [3" id="c-fr-0003]
    3. A method according to claim 1 or 2, characterized in that it comprises a step of eliminating all possible sources of incondensable gas, from the preparation of the product to the closure of the container, including when filling the containers. containers, so as to ultimately ensure a deep vacuum in said container.
    [4" id="c-fr-0004]
    4. Method according to one of claims 1, 2 or 3, characterized in that the degassing provided at the times of sterilization of the containers, the filling of the container and its closure are by injection of superheated steam to over 130 ° C by imposing a rotary movement of the vapor in the spaces concerned, of tourbillon or vortex type, capable of eliminating all trace of air in a very limited time and of replacing it exclusively with superheated steam capable, during its cooling and its condensation, to cause the placing of the container under said deep vacuum, the steam being injected at a temperature, a rate and for a time adapted to allow sterilization of the areas concerned.
    [5" id="c-fr-0005]
    5. Method according to one of the preceding claims, characterized in that it comprises a step of creating continuously in the conditioned containers of the thermodynamic conditions necessary for all the heat exchange in the container to go to the boiling point and of condensation, allowing to exploit the latent heat of vaporization of the water to evacuate the heat of the container.
    [6" id="c-fr-0006]
    6. Method according to one of the preceding claims, characterized in that it implements a homogeneous boiling of the product, said boiling being normal for materials containing water and placed under the vacuum envisaged, allowing continuously impose a homogeneous cooling of the food in the already closed containers.
    [7" id="c-fr-0007]
    7. System for pasteurization or continuous sterilization under deep vacuum, food products, characterized in that it comprises: • means (20) for degassing the bulk product, these means can be either a system for putting under empty, either a cooking system that naturally induces degassing, or a cooking under vacuum; Means (21) for sterilizing and degassing the containers using at least superheated steam as an agent, this vapor inducing at least one complete degassing of the inside of the container, sterilization (22) and cooling means (33) ) of the bulk product, said cooling means being placed at the outlet of said sterilization means; • means (24) for separating and disinfecting the lids, using the superheated steam as a means of disinfection, this vapor inducing a degassing of the environment of the lid, which contributes to the degassing of the entire system; Filler means (23) permitting the evacuation of the incondensable gases in the container, and in any case allowing the sterile filling and filling of the foodstuffs in the container, the filling means (23) being able to be installed in series; on a filling line (32); Means (27) allowing both the manipulation of the lids, the injection of steam, the closing of the containers filled with food and the cooling of the containers by a cold shower, means also called "closing head"; An enclosure (29), located upstream of the entire vacuum closure system and including a filling line (32), and thus located just before entering the enclosure (28), and being connected thereto hermetic without possibility of air intake, said enclosure (29) to be under slight overpressure of superheated steam; An enclosure (28) maintained in optimal sterile state by the initial injection of superheated steam at the beginning of the process and then kept under steam, this enclosure including the entire sector of exchange of lids and containers filled between first and second , third and fourth carousels (1, 2, 3, 4), the vapor escaping only in height through the inlet of the lids at the tubular store and the entry and exit of the first and fourth carousels (1, 4); Means for transferring the containers between the other means which guarantee the maintenance of the degassing and the sterile state of the products and containers; Means for braking the entry of air into the enclosures (28 and 29) under superheated steam, such as, for example, flexible skirts placed at the exits of said enclosures.
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    同族专利:
    公开号 | 公开日
    EP3189737A1|2017-07-12|
    ES2740731T3|2020-02-06|
    US20170197744A1|2017-07-13|
    EP3189737B1|2019-05-15|
    FR3046527B1|2020-11-27|
    PT3189737T|2019-08-26|
    CA2953428A1|2017-07-07|
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    IT201900017153A1|2019-09-25|2021-03-25|Andrea Darecchio|METHOD AND APPARATUS FOR PASTEURIZATION OR STERILIZATION UHT-ST AND ASEPTIC PACKAGING IN MODIFIED ATMOSPHERE MAP STERILIZED IN RIGID PRIMARY PACKAGING IN RESPECT OF CONSUMER HEALTH AND THE ENVIRONMENT, OF FOOD PRODUCTS WITH SOLID OR PULSE, OR PULY, OR PULY WITHOUT SOLID PIECES, OR STILL DRINKS, COSMETICS, DRUGS AND SIMILAR, MEDIUM OR LONG STORAGE AT ROOM TEMPERATURE|
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    法律状态:
    2017-01-27| PLFP| Fee payment|Year of fee payment: 2 |
    2017-07-14| PLSC| Publication of the preliminary search report|Effective date: 20170714 |
    2018-01-30| PLFP| Fee payment|Year of fee payment: 3 |
    2020-01-30| PLFP| Fee payment|Year of fee payment: 5 |
    2021-01-29| PLFP| Fee payment|Year of fee payment: 6 |
    2021-11-05| TP| Transmission of property|Owner name: AUXILIAR CONSERVERA, S.A., ES Effective date: 20210927 |
    2022-01-25| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1650122A|FR3046527B1|2016-01-07|2016-01-07|CONTINUOUS PROCESS AND SYSTEM FOR PASTEURIZATION OR STERILIZATION OF FOODSTUFFS IN A RIGID CONTAINER FOLLOWED BY ITS DEEP VACUUM CLOSURE BY ROTARY STEAM INJECTION|FR1650122A| FR3046527B1|2016-01-07|2016-01-07|CONTINUOUS PROCESS AND SYSTEM FOR PASTEURIZATION OR STERILIZATION OF FOODSTUFFS IN A RIGID CONTAINER FOLLOWED BY ITS DEEP VACUUM CLOSURE BY ROTARY STEAM INJECTION|
    CA2953428A| CA2953428A1|2016-01-07|2017-01-04|Continuous process and system for pasteurizing or sterilizing food in a rigid container followed by deep vacuum sealing by rotary steam injection and fast homogeneous cooling|
    US15/399,580| US20170197744A1|2016-01-07|2017-01-05|Continuous process and system for the pasteurization or sterilization of foodstuffs in a rigid container followed by the deep-vacuum sealing thereof by rotary steam injection and homogeneous rapid cooling|
    PT17150430T| PT3189737T|2016-01-07|2017-01-05|Continuous method and system of devices for pasteurising or sterilising foodstuffs in a rigid container followed by deep-vacuum sealing of same by rotary steam injection and uniform rapid cooling|
    EP17150430.1A| EP3189737B1|2016-01-07|2017-01-05|Continuous method and system of devices for pasteurising or sterilising foodstuffs in a rigid container followed by deep-vacuum sealing of same by rotary steam injection and uniform rapid cooling|
    ES17150430T| ES2740731T3|2016-01-07|2017-01-05|Continuous process and system of devices for pasteurization or sterilization of food products in a rigid container followed by deep vacuum closure by rotary steam injection and homogeneous rapid cooling|
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