MX2007013692A - Jet dispenser system comprising cylindrical cavities. - Google Patents

Abstract

The invention relates to a jet dispenser system which is used to dispense a frozen or refrigerated product at ambient temperature, said system comprising cylindrical cavities, seal-equipped valves and a system for the opening/closing of lock chambers that are used for the jet-dispensing of the product. The invention is characterised in that it comprises: (1) a system for the jet-dispensing of the product, formed by a) a product storage area, b) a system of lock chambers and c) a system of valves with a cylindrical cavity; and (2) means for transmitting the rotational motion of the mechanism which is fixed in the jet-dispensing system, which actuates the components of the device and which controls the rotational functions of the cylindrical cavity and the opening and closing of the lock chambers, as well as simultaneously dispensing the product to the exterior.

Description

SYSTEM SUPPLIER OF PRODUCTS WITH CYLINDRICAL CAVITY FIELD OF THE INVENTION The present invention relates to a system dispenser of products, and more particularly to a system dispenser of products at room temperature, refrigerated or frozen, which supply products from one part of the system to another. Also, a system of dispensing cavities with a completely new mechanism is described.

BACKGROUND OF THE INVENTION In the prior art a wide variety of dispensing devices or dispensers of products have been described. These devices include mechanical, electronic and electromechanical systems to supply the product they contain. Some of these systems produce product in its natural state, at room temperature, such as fried foods, sweets, etc. Other systems supply products that require refrigeration or freezing for the preservation of food, such as ice cream, ice lollipops, packaged products, etc. The latter also require the cooling system, a system supplier of the products, which because they are food at a temperature lower than the ambient temperature, generates energy losses, condensation and humidity at the time of expelling the product abroad. Various types of product dispensing machines, or vending machines, are known in the state of the art. These machines have mechanical and electromechanical means to supply the selected product.

The main purpose of vending machines or vending machines is to supply a product, previously packaged or in its natural state, from inside the machine, to the outside, where it is received by the user. The main functions of the product vending machines are to contain a specific product, protect it from the outside and keep it in good condition, be visible in order to be selected, either visually or by means of a graphic element, and have a device that supplies it to the outside, in order to be used by the consumer. Depending on the type of machine, there are those that have a purse, which can be electronic or mechanical, where coins are deposited to buy the selected product and that activate the supplier system; and those that are operated manually, without a purse, previously paying for the chosen item, and being supplied by the employee of the establishment. In the US patent application number US2002 / 0040915 A1 an example of a vending machine is shown that supplies product in its natural state, such as ice cream, and that does not have a purse system for payment. This system supplies ice cream in a colloidal, or pasty, completely amorphous state, and requires the operation of some manager. The patent number EP0755032 shows a vending machine of frozen packaged product, which has already known freezing systems, as well as a product dispensing system. This system supplies product blocks of regular dimensions. These vending machines generally operate with electric current, and have different mechanisms that supply the selected product, which is located in a chamber isolated from the outside, with cooling or not, depositing it in an open tray or some other device that is accessible to the user.

This isolated chamber or product cellar, may contain a single type of product, or different products. It can be completely covered without showing the product to the consumer, or it can be displayed through a glass front, usually a door, where the product is stored. Examples of product vending machines include machines that have a glass front, which allows to see the contents of the device, to make the visual selection of the product and its brand. These machines generally display and supply products of different sizes, brands and presentations. Other types of vending machines include those manufactured with non-transparent fronts, and where the product is selected by means of a graphic or button with the brand or graphic of the product. These are generally used for beverages where what is sold is a single type of product, but with different presentations. These dispensing machines, depending on the product, may or may not have a refrigeration or freezing system for the preservation of the exposed foods, so that they are in optimum conditions when being supplied. The cooling means of the prior art consists of cooling by means of forced air, convection and transfer cooling.

Various refrigerators and freezers used for food and beverages are known in the art. In the case of refrigerated or frozen products, the main problem of the assortment in vending machines, is that when the product is expelled from the chamber with freezing temperature, a door or mechanism is opened that ejects it towards an outer tray, where The buyer can take the product that is at room temperature.

This creates that the frozen product when touching the air coming from room temperature generates a condensation on its surface, generating drops of water and supplying the wet product. Another problem is that the opening of the door allows access to the interior of the air freezer with a higher temperature than the interior, generating condensation, loss of temperature, and energy inefficiency due to higher electricity consumption to compensate for internal temperature losses. Another problem is that current product assortment systems are based on packages or containers with defined shape, for example cylinders or solids of revolution. In the case of amorphous packaging, or flexible packaging products, such as frozen or sweet pallets, there is no suitable dispenser that allows the product to be stored in an orderly manner and supplied in combination with a freezing or refrigeration system. Therefore, the present invention corresponds to a system dispenser of refrigerated product, frozen or at room temperature, by means of cylindrical cavities, which supply the product from the inside to the outside, simultaneously releasing one product and holding the next. In the case of being a frozen or refrigerated product, the system allows the product to be supplied from the inside at refrigeration or freezing temperature, to the outside at room temperature, without loss of temperature or condensation. The applications of the invention consist mainly of vending machines for various types of products, refrigerated and frozen products, whether or not they have a purse, and which have a defined form or special exterior design to function as a point of sale, installed in certain places. public, convenience stores and miscellanies, extolling the brand and the form or product that it contains for easy identification, and that show diverse options of flavors or presentations.

Still another application of the invention is to install it in existing refrigeration or freezing systems, furniture and showcases of products, and where the product to be supplied has no definite shape, such as frozen pallet packages, cones, frying bags, etc. . Another application of the invention is in furniture, refrigerators or freezers for supermarkets and convenience stores, without a purse, where the buyer can access the product by means of a button that operates the mechanism, to pay it later in the outlet box.

SUMMARY OF THE INVENTION One of the main problems associated with the sale of a food or product in assortment machines is presented at the time of delivery. Once the right product is chosen by the consumer, an electrical, mechanical or electronic mechanism is required to trap the product and deposit it somewhere in the machine that is accessible to the buyer. These systems have been extremely complex, directly affecting the cost of the machines that supply them, due to the large number of parts necessary to carry out the operation. In the case of refrigerated or frozen commercial foods or drinks in product dispensing machines, the problem arises when dispensing it from the inside of the appliance to the outside, where it can be reached by the potential consumer. This operation generates moisture from the environment entering the interior of the refrigerator, which condenses, generating a loss of temperature inside, as well as a higher energy consumption, in addition to supplying the wet product, the effect of this condensation. It is therefore the object of the present invention to provide a product delivery system at room temperature, refrigerated or frozen, by middle of rotating cylindrical cavities that activate a system of locks, which release the product, and retain the previous one. Another object of the present invention is to provide a dispensing system for frozen products with a temperature insulating system, which produces refrigerated or frozen product from a freezing or cooling temperature to ambient temperature without loss of temperature or condensation. Another object of the invention is to provide a combined system of rotating cylindrical cavities, which have a special arrangement of valves, operated manually or mechanically-electric, and which can also be installed in closed furniture, refrigerators or freezers. Still another objective of the present invention consists of a dispensing system, which supplies the product chosen by the consumer to the outside, and operated by a manual, mechanical, electronic or electromechanical mechanism. Another object of the invention is to provide a product dispensing system, which uses a same rotary cylindrical cavity to supply two different types or categories of products, arranged in vertical arrangement, and which are retained by the lock. Another object of the invention consists in supplying product that also does not have a definite, cylindrical or rectangular shape, as in the case of carbonated drinks or packaging of diverse products, but it allows to supply products with flexible and amorphous packaging, such as frozen palate packages. and others. Another object of the invention is to provide a dispensing system with a small number of parts, which generates a remarkable commercial advantage. The aforementioned objectives are achieved by means of providing a product dispensing system comprising a mechanism dispenser of product with mechanical and electronic-mechanical means, with a system of locks, valves and rolatoria cylindrical cavities.

A preferred way to carry out the invention is to use materials of industrial manufacture in series, as well as to achieve the movement of supplying the product by means of electronic or mechanical elements, with a mechanical purse that allows to supply the product. Olro way to realize the invention, consisto in achieving the action of assortment of the product by manual means, without purse.

DESCRIPTION OF THE FIGURES Fig. 1 is a schematic view of the freezer apparatus, in accordance with the present invention. Fig. 2 shows a view of the components of the system in isomelic, with a cut to show the hidden parts. Fig. 3 shows a detail of one of the side parts. Fig. 4 shows an isometric front view of the container cylinder. Fig. 5 shows a posterior isometric view of the container cylinder. Fig. 6 shows a view of the lock. Fig. 7 shows an explosive view of the lock and its component parts. Fig. 8 shows an isometric detail view of the arrangement of the locks. Fig. 9 shows a front view of the valves, with the parts that compose it, and the spaces that contain the product vertically. Fig. 10 shows a front view in section of the locks mechanism, the exempted valves and the top valves. Fig. 11 shows a frontal view of the lock mechanism, the valves, the meíálicos separators and the cylindrical container in the closed position, with two products in vertical arrangement.

Fig. 12 shows a view similar to the previous one, where the beginning of the rotation of the cylindrical cavity and the moment in which the lock is accommodated is shown.

Fig. 13 shows a similar view to the previous one where the course of the rotation of the cylindrical cavity is shown and makes the cutting of this with the circular protuberance of the lock. Fig. 14 shows a visor similar to the previous one, where the cut of the cylindrical cavity pushes the lock, causing it to project its upper puncture, due to its semicircular shape, by apprehending the compression spring. Fig. 15 shows a view similar to the previous one, where by the effect of the thrust of the cut of the cylindrical cavity, the lock performs a movement that imprisons the upper product, holding the lower product at the same time.

Fig. 16 shows a view similar to the previous one, where it can be seen that the lock imprisons the upper product, totally releasing the lower product, which slides and falls into the cylindrical cavity. Fig. 17 shows a view similar to the previous one, where the container cylinder returns to its starting position, with a product inside it, while holding the previous product with the lock. Fig. 18 shows a visia similar to the previous one, and where the product of the cylindrical cavity is expelled towards the exterior of the system, while holding the immediate previous product.

DETAILED DESCRIPTION OF THE INVENTION The product dispensing system of the present invention comprises a product storage device, a system for opening locks to supply it, and a valve device with cylindrical cavities that eject the product from the inside of the appliance to the outside, in an orderly manner.

In the apparatus of the present invention the product is removed from the inside of the product warehouse, operated by a mechanism, with a system of valves that keep the interior of the apparatus always isolated from the outside, either at ambient temperatures, or in cold conditions inside. The device comprises stages of opening and closing the locks by means of an electromechanical mechanism. The union of the aforementioned single operations results in a disposilive dispenser, with utility in furniture and showcases, specially designed furniture, and refrigerators and freezers, where the conservation of energy and time, and the assortment of a particular product in a simple and fast way, allow to produce a preserved and in good condition. In accordance with Fig. 1, the apparatus of the present invention comprises a dispenser rack (1A) formed by assembled elements, which as a whole form the production sys- tem system. The rack (1A) comprises means for the storage, selection and assortment of the products contained in the device. Depending on the requirements of the market, the interior and exterior design of the device can vary in its dimensions and shape, to accommodate different capacities and type of product inside. The spout rack (1A) that have the shape or interior design of the cabinet or refrigerator can vary depending on the type of model, measurements or product to be contained, being manufactured in a variety of different materials, such as metal sheets, plastic sheets, thermo plastic formed, plastic injected, plastic exempted, broken molding and others. For industrial applications it is preferred to make the model with metal sheet and formed or inert pieces. According to Fig. 2, the production system is formed by a series of dividers (2A), which can be manufactured in any machine, preferably metal, and whose function is to order vertically the production to be supplied. The separator (3A) has the function of acting as a separator of the locks (12A), and housing in its interior an axis that supports said locks. This separator (3A), also has the function of directing the production towards the interior of the device, and it can be manufactured in diverse materials, such as die-cut sheet, plastic, or others. The space created between the separator (3A) and the dividers (2A), create a warehouse where the product is stored in an orderly manner, in vertical arrangement. The smaller gear (4A) is inserted on the gear shaft (6A), and its function is to provide the transmission energy to the larger gear (5A). Both gears can be manufactured in various materials, such as engineering plastics or nylon. The gear shaft (6A) may be attached to the shaft of an electric motor that provides traction, or may simply be attached to a manual operating handle. The larger gear (5A) is inserted directly into the axis of the cylindrical cavity (11A), so that when turning, transmits the directional energy to the cylindrical container. The valve (8A) is made of preferably exempted plastic or metal material, and its function, in addition to joining the limpets (7A) to each other, by means of screws (10A), is that of providing a circular contact area for the cavity. cylindrical (11A). The cap valve (9A) is also preferably manufactured in plastic or exempted metal, and has a shape similar to the valve (8A), but it is remailed in a sturdy manner on one of its sides. The cylindrical cavity (11 A), has the function of receiving the product, containing it and depositing it from one side of the system to the other.

The locks (12A), have the function of supporting and imprisoning the product to be supplied, and are made of preferably injected plastic. These locks (12A) are supported by a metal shaft (13A), which crosses from one side to the other of the device, being inserted into the inner walls of the limpets (7A). According to FIG. 3, the lateral limpets (7A) have a series of receptacles on the inside that allow the other parts of the device to be housed. The inner slot (1 B) allows to receive the dividers (2A), being slightly wider than these, so that they can slide easily. This slot (1A) has a stop (2B) that marks the maximum insertion limit of the dividers (2A). The pull-out (3B) of the separator (3A) allows inserting the separator (3A), sliding it downwards, and has a separator stop (4B) that marks the maximum insertion. The hole in the lid (5B) allows the metal shaft (13A) to be assembled in its interior by pressure, which passes through the covers (7A) from one side of the device to the other. Both covers (7A) are identical, such that the complete system is symmetrical. The circular kick-out (6B) allows to lodge inside it the cylindrical cavity (11 A), allowing its axis to pass through the hole for the cavity (7B). Take out circular (6B) so that, as shown in Fig. 4, the barrel of the cylindrical cavity cylinder (9C) is flush, preventing the product from getting stuck when being supplied. Fig. 4 shows the cylindrical cavity (11A). Said piece has a cylindrical body (1C) which can be solid, or hollow, and depending on the application will be filled with various materials, such as polyurethane foam, to act as an insulator, in case of having cooling. Said cavity has an axis (2C), with a straight cut (7C). On this axis the larger gear (5A) will be inserted. The straight cut (7C) acts as wedge, avoiding the sweeping motion of the gear. In turn, the larger gear (5A) has this same cut. The cylindrical cavity has a container area (4C), where the product to be supplied will be housed. This area may change shape and dimensions to accommodate different types of products. According to Fig. 5, the cylinder cover (9C) prevents the product from leaving the container area (4C), besides having the cylinder axes (2C and 3C). The shaft (3C) is of smaller dimensions, since it does not support any additional part and only serves as a guide for the cylindrical cavity. The chamfer (6C) of the cylinder allows the products to slip more easily into the container area (4C), preventing them from clogging. In Fig. 5, the cylindrical body (1C) has a straight cut (5C), which gives the traction to the locks, on both sides of the piece, symmetrically. This cut has a cant (8C) that operates the lock (12A) in one of its parts. As seen in Fig. 6, the lock (12A) has a specific shape and is formed by assembled elements. Fig. 7 shows the parts that make up the lock (12A), which is mainly formed by a left body (2D) and a right body (1 D). Both bodies have an arched inner cut (7D) where a compression spring (9D) is inserted. Said inner cavity (7D) has a dimension slightly larger than the diameter of the meíal axis (13A) which supports the locks (12A), and which in turn has a protuberance or step (8D), which prevents the spring from coming off of the pieces once assembled, imprisoning them in their interior. The left body (2D) has a pair of pins (3D) that are inserted into the drill holes (4D) of the right body (1 D), acting as assembly guides.

In addition, the flat surface (6D) of both bodies, allows to join both parts with glue. Both bodies have a shelf (5D), where the product rests to supply, and that together create a greater surface of condensation. The circular bulge (10D), is the part of the piece that is in constant contact with the cylindrical cavity (11A) and where the traction of the cylindrical cavity (11A) is transmitted to the lock (12A). The rib (11 D) of the lock (12A), serves to structure the piece and give it greater rigidity. The puncture (12D) of the lock (12A) serves to imprison the previous immediate production. Fig. 8 shows the separator (3A) of the locks (12A) on the assembled device. This separator (3A) has a series of cuts (1 E) that serve to house the locks (12A) to a demineralized distance, thus preventing them from moving from their position. Said support has a plate (2E) where a hole (3E) is located, which serves to fasten the support to the side limpets (7A), by means of a screw (10A) that joins both parts by another hole (4E) located on the surface of the covers, avoiding with this that the support can move from its position. Said support comes with a triangular finial (5E), which allows the products to be supplied to be directed towards one side or the other of the support. Fig. 9 shows the arrangement of the parts in idandem, with any cylindrical cavities and their respective devices, and where the spaces are shown between the separators (3A) and the dividers (2A) that create a space (ES) where it is housed the product to be supplied (P1 and P2). The function of the space between dividers (2A) is to store the produce to be supplied, be it drink, food, medicine or money. The lower volume of said compartment may vary depending on the lipo, dimensions, shape and capacities of the product to be exhibited.

This arrangement shown in Fig. 9 allows eight different types of product to be supplied. However, the number of cylindrical cavities and their devices may be of a greater or lesser number, depending on the product and lipo of the assortment machine. This compartment may comprise movable dividers to subdivide the interior space of the compartment, and thus store the inner product in an orderly manner. These interior dividers can be manufactured from various materials, from injected plastics, electro-painted wire and others. Said product is arranged vertically, one above the other, in the order illustrated, and resting on the shelf (5D) of the lock (12A). As corresponds to Fig. 9, said accommodation shows the valves (8A), the cylindrical cavities (11 A) and the cap valves (9A). In Fig. 9, the smaller gear (4A), when turning, transmits its energy to the larger gear (5A), which is fixed to the axis of the cylindrical cavity (2C), and therefore transmits the energy of turn. This energy of rotation of the minor gear (4A) that makes the system move can be obtained by manual, mechanical, electro-mechanical or electronic means. The rotation movement can be clockwise or counter clockwise, depending on the type of product that is requested to supply, either on one side or the space of the spaces (ES) for the product, and which may have different flavors or specifications of the same production presentation, or different products. According to Fig. 10, each valve (8A) has in its design a series of inputs (6F), which allow to house by means of pressure six seals (2F) that are in direct contact with the cylindrical cavity (11 A). Said seals are manufactured in flexible material, so that they are in direct contact and at all times with the cylindrical body (1C) of the cylindrical cavity (11 A).

These stamps (2F) may vary their shape and dimensions depending on the needs of the products to be supplied. These seals (2F) are manufactured with flexible, injected or extruded material, with high resistance to freezing without losing their plastic qualities. The chamber (1 F) created between the seals (2F), the cylindrical cavity (11 A) and the valves (8A, 9A), acts as an insulator, in case the system is sealed and has cooling or freezing, creating an air chamber. In turn, the inside of the valve (7F) can be filled with insulating materials, such as polyurethane foam or fiberglass, so that the assembly is completely isolated from the interior and exterior of the device, should the with refrigeration. The cooling mechanism of the freezer or refrigerator unit that may optionally include the system may consist of any gas compression refrigeration cycle known in the art, for example those employing mixtures of halogenated hydrocarbon gases or ammonia.

Each valve has two protuberances (5F) that allow them to be joined, by means of screws (10A) to the lateral limbs (7A). The cap valve (9A) has only three seals (2F) in an arrangement and arrangement identical to that of the valves (8A), but only on the inner side of the device. The opening and closing device of the locks (12A) comprises mechanical and / or electromechanical elements for actuating them, and allowing the free passage of the products to the valve arrangement. This device is operated from the outside manually, either mechanically or electromechanically, either by turning a knob, or by pressing a button. The valve device contains mechanical means that prevent heat transfer and decrease in temperature to the bottom of the refrigerator. The function of the system pump of product with cylindrical cavities, includes the following eíapas: A) Storage; B) Product selection; and C) Product assortment A) Storage As illustrated in Fig. 11, the space (ES) created between the dividers (2A), and the separators (3A) allow accommodating products accommodated vertically therein. Although only two products are illustrated, the divisors as well as the disposicle as a whole may have larger dimensions, in such a way that it allows a greater number of products to be contained per vertical row.

This vertical row of products rests on the ledge (5D) of the lock (12A). As seen in Fig. 11, the circular protrusion (10D) of the lock (12A), is in permanent contact with the surface of I cylindrical cavity (11A). Said lock (12A) rests on the metal shaft (13A), which crosses the entire length of the lock by its arched inner cut (7D), inside which is the compression spring (9D). This figure shows the cylindrical cavity (11A) in its closed position, with the container area (4C) of the cylinder open downwards.

B) Selection of the product According to Fig. 12, the cylindrical cavity (11A) thus rotates directly to the rotation movement exerted by the greater gear (5A) attached to the axis of the cylindrical cavity (2C). At the moment of rotation, the straight cut of the cylindrical cavity (5C) comes into contact with the circular protuberance (10D) of the lock (12A), which performs a downward movement maintaining its contact at all times with the cylindrical body (1C) of the cavity. Fig. 13 shows the moment when the cant (8C) of the straight cut (5C) of the cylindrical cavity (11A) makes contact with the circular protrusion (10D) of the lock (12A), pushing it and transmitting the rotary movement in linear motion. Fig. 14 shows the route taken by the lock (12A), which when making a linear movement originated by the cylindrical cavity (11A), presses the lock (12A) which, due to its arched design, transmits the movement in an ascending manner . This movement generates that the separator (3A) that is in a fixed position, serves as a guide, since the arched inner cut (7D) of the lock (12A) functions as a channel that moves to mud along its shape . This movement causes the compression spring (9D) inserted in the lock (12A) to be compressed, the metal shaft (13A) acting as the maximum limit of the spring, and in turn, allowing the tip (12D) of the lock, protrudes from the metal separator (3A) through one of its cuts (1 E). This movement of the lock (12A) generates that the ledge (5D) of the lock is hidden inside the metal separator (3A), in its lower part, and the tip of the lock (12D) protrudes from its upper part. Fig. 15 shows the moment in which the lock is in simultaneous contact with the product (P1) of the lower part on the shelf (5D), and with the higher production (P2) with the puncture of the lock (12D), due in part to the semicircular design and dimensions of the lock (12A). This form and design may vary depending on the lipo, dimensions and shape of the product to be supplied, but maintaining the arched shape of the device. At the moment of rotation and action of the movement, the surface of the cylindrical cavity (11A) was in contact with the seals (2F) creating two closed chambers on each side (1 F) where the air and humidity of the external environment is trapped.

C) Production assortment Fig. 16 shows the moment in which, as a result of the travel made by the lock (12A), the upper product (P2) is trapped by the divider (2A) and the tip of the lock (12D), which protrudes in its maximum of the separator (3A), while releasing the lower product (P1), which slides downwardly into the container area (4C) of the cylindrical cavity. At this time, the shelf (5D) of the lock (12A) is fully inserted deniro the metal separator (3A), allowing the free passage of the lower product (P1). As seen in Fig. 17, the cylindrical cavity (11A) now performs the counterclockwise movement, returning to its initial position. This movement causes the upper product (P2) to descend vertically as a result of gravity, and to be supported by the shelf (5D) of the lock (12A), while the lower production (P1) rotates deniro and June with the Cylindrical cavity (11A). In Fig. 18, the cylindrical cavity (11A) has returned to its closed position, ejecting the production and supplying it to the outside, passing it from one side of the device to another. The combination of the aforementioned operations results in the simultaneous rotation of the locks (12A), which allow the product to pass to the valve device, falling in the interior of the cylindrical cavity (11A). The assortment of the products is repelled every time a product is selected. In the event that the spout rack (1A) is located inside a closed cooling or freezing system, the system will allow to supply products from inside the refrigeration system, to freezing temples, to the outside of the system, at room temperature . Seals of the valves (2F) as well as the formed chamber (1 F) between the valves (8A) and the cylindrical cavities (11 A), June with insulating material inside the valves and the cavity Cylindrical, they allow an isolated system that guarantees that temperature is not lost, nor is condensation created in the products to be supplied. The illusionary team in the figures shows a system that is the source of the product, which stores, preserves, protects and distributes products at ambient temperatures, cold or frozen. This system can be used in a refrigerator or freezer unit, and is applicable in department stores, supermarkets, convenience stores and various miscellaneous items, also being used as a means of promotion and point of sale (POP) to adequately display various products, highlighting the values Of the brand. It will be evident that for a person skilled in the art the type of mechanism used to operate the cylindrical cavity (11A) and the locks (12A), as well as that of product selection, can change. However, the system of cylindrical cavities, with a system of locks operated by these, allow a product to pass from one side of the system to another, supplying it to the outside, it is the combination that makes the system something unique. In addition, the possibility that the system can be placed inside a hermetic structure, as in the case of the inside of a refrigerator or freezer, supplying a product from a cold or frozen chamber to another at room temperature, without causing loss of temperature and condensation, supplying Simultaneously the product, makes the system can have multiple industrial and commercial applications, to supply products such as ice cream, medicines, beverages and others, which require preservation by means of cold.

Claims (20)

1. A system for producing ambient, refrigerated or frozen products, characterized in that it comprises: (1) a product dispensing system, consisting of a) an area for storing product, b) an arrangement of locks, and c) a valve device with Cylindrical cavity, (2) means for transmitting the movement of the rotational direction of the mechanism, fixedly disposed in the spout system.

2. The area for storing product according to claim 1, formed by a series of mobile dividers and separators, between which a space is created to contain goods arranged vertically.

3. The lock device according to claim 1, formed by an arrangement of tandem locks inserted along a honeycomb axis, which is inserted in the lower part of the façades, and whose locks have a spring in their interior. compression that allows the lock to return to its original position.

4. The locks arrangement according to claim 3, wherein a separator introduces a series of cuts that allow a fixed position to the locks, allowing movement of vertical translation, but not along the axis, and allowing their free movement vertical at the moment of being operated by the mechanism, where said separator had a triangular finish to easily direct the product to supply to one side or the other of the disposilive.

5. The locks arrangement according to claim 1, wherein each of said locks has a compression spring and a channel through which the metallic axis passes through.

6. The locks device according to claim 1, wherein each lock has a semicircular shape, and where there is a shelf to support the produelo to supply, a puncture that protrudes at the time of completion the operation and that imprisons the immediate previous product, and a circular protuberance, which is at all times in direct contact with the surface of the cylindrical cavity.

7. The protrusion according to claim 6, which is operatively associated with the cylindrical cavity, and wherein the ro- tation movement of the cylindrical cavity is irreversibly milled by means of a strong cut and a camber on the surface of the cavity. cylindrical

8. The valve arrangement of the production jet system according to claim 1, which are associated with a cylindrical cylindrical cavity, which allows the product to be supplied, contained and supplied to the other side of the system. The valve arrangement according to claim 1, wherein said valves contain a series of seals, which are in constant contact with the surface of the cylindrical cavity, and which create an air chamber that functions as an insulator between the upper part and the bottom of the spout rack. 10. The dispensing system of product according to claim 1, wherein the valve system has valve seals in such an arrangement that they allow to be in continuous contact with the circular surface of the cylindrical cavity, even when it rotates, creating an interior chamber with air that acts as a temperature insulator. The valve device according to claim 1, wherein said valves include valve closures, both contain entries for inserting several seals. The valve device according to claim 11, wherein said valves and finials have a concave shape to be associated with the former form of the cylindrical cavity. 13. The cylindrical cavity according to claim 1, which presents a container area where the production is stored and supplied, and wherein said The cylindrical cavity has one axis, operatively associated with a larger gear, which transmits the rotational movement. 14. The cylindrical cavity according to claim 1, which has a strong cut and a cant, which pushes the lock by transmuting the rolling motion to one of shunting. 15. Valves with cylindrical cavity according to claim 1, which are filled with insulating material, which allows the use of the dispensing system in closed furniture, such as refrigerators and freezers, avoiding the loss of temperature and humidity at the moment of supplying a product from its inior to the previous one. 16. The means for transmitting the movement according to claim 1, which comprise a smaller gear associated with an axis, a greater gear operatively associated with the smaller gear, which transmits the movement to the axis of the cylindrical cavity, said mechanism in the top of the structure of the production jet system and which controls the opening and closing functions of the lock. 17. The movement according to claim 16, wherein said rolling motion on the smaller gear transmits the movement energy manually, electrically, electronically or electromechanically. 18. The product dispensing system according to claim 1, which allows to produce product from refrigeration or freezing temperatures up to room temperature, without any condensation or humidity that enters the system or adheres to the product to be supplied. 1

9. The product dispensing system according to claim 1, which allows to supply ambient temperature products, frozen or refrigerated, of amorphous, non-syiric packaging and flexible wraps. 20. The product dispensing system according to claim 1, having insulating chambers of temper- ature, formed by air contained within the valve walls, valve seals and cylindrical container, and that prevent the entry of exi erior air, as well as the expulsion of air from the interior.