ES2689335B2 - COMPACTED ICE MANUFACTURING SYSTEM - Google Patents

Description

DESCRIPTION

COMPACTED ICE MANUFACTURING SYSTEM

FIELD OF THE INVENTION

The present invention is framed in the field of ice making industry. More specifically, the invention relates to an ice making system compacted from crushed or flaked ice.

BACKGROUND OF THE INVENTION

At present, various processes for the production of compacted ice at the industrial level are known. These processes can be divided, in general, into two groups. The first group is based on a direct method of obtaining compacted ice, consisting of generating the ice blocks directly, through a thermodynamic cycle, in which cold is generated and the water gradually freezes. These methods have the disadvantage that thermal processes are slow, and the production of compacted ice from remarkable dimensions, such as the typical dimensions of ice cubes, is relatively low.

The second known group of processes is based on an indirect method, in which compression compacted ice is obtained, from crushed ice or flakes. These scales are obtained by applying the direct method, explained above, with the advantage that being smaller scales and not requiring their production under a specific form, it is a faster process than the formation of ice cubes or blocks of compacted ice of larger dimensions. Within these processes, the compaction of the known crushed ice is made from remittances that are batch processed, discontinuously. Therefore, the productivity of these processes is also low. An example of this type of process is described in patent ES 2402968 B1.

This patent discloses a system that has a hopper or upper tank, where crushed ice is stored. A mold is fed through a hole in the lower part of said hopper where, by the compressive action of two linear and horizontal pistons, the ice is compressed and compacted ice cubes are formed. Finally, the pistons are separated and the cubes are extracted. The system described, therefore, is treated of a linear, discrete compression system that does not allow large productivity.

The present invention is oriented to solve the problem of the low productivity present in the prior art procedures, through a novel compacted ice manufacturing system, based on rotary means of crushing ice compaction capable of operating continuously , thus achieving productivities substantially superior to those of known technologies.

BRIEF DESCRIPTION OF THE INVENTION

As described in the previous section, the object of the invention relates to a system for the manufacture of compacted ice from crushed and / or flaked ice, designed to significantly increase the production rate against the alternatives of the state of the technique.

Said system preferably comprises:

- An intake subsystem, configured with means to feed crushed ice to the system.

- A crushed ice compaction subsystem, comprising at least one pressing module against which crushed ice is compacted, and a compression module equipped with means for generating compression forces through the movement of one or more cylinders of pressing.

- A drive subsystem of the compaction subsystem.

Although reference will be made in this description, mainly, to the compaction of crushed ice, it should be understood that this term also includes flake ice as a possible base material for compaction, without altering the main object of the invention.

Advantageously, the compaction subsystem of the invention also comprises one or more rotary crusher ice crushers, arranged between the pressing module and the compression module, arranged so that its rotational motion allows the crushed ice to be transported and the compacted ice during its manufacture. Additionally, the drive subsystem is equipped with means to propitiate the rotation of the rotating platforms while compacting the crushed ice.

In a preferred embodiment of the invention, the intake subsystem comprises an upper intake hopper, equipped with manual or automatic ice feeding means.

In another preferred embodiment of the invention, the rotary molding platforms comprise one or more interchangeable patterns equipped with one or more molding holes.

In another preferred embodiment of the invention, the compression module comprises a plurality of wheels connected to the compression cylinders, and guided by one or more corresponding guide tracks, so that the passage of the wheels through the guide tracks generates the linear movements of said compression cylinders.

In another preferred embodiment of the invention, the wheels are distributed as a group of outer wheels and a group of inner wheels in the compression module.

In another preferred embodiment of the invention, the guide tracks have paths of different heights on which the wheels slide.

In another preferred embodiment of the invention, the compression module also comprises a set of lower pressing pistons, and a set of lower wheel carrier arms and corresponding upper thrust arms, which accompany the linear movement of the wheels, to compress the crushed ice against the pressing module.

In another preferred embodiment of the invention, the compression module comprises at least one dividing rotary platform, configured to insulate against water the part of the compaction subsystem that is located between the inner wheels and the rotational molding platforms. More preferably, the module comprises, between said dividing rotary platform and the rotational molding platform, a plurality of substantially vertical structural arms.

In another preferred embodiment of the invention, the rotary molding platform is connected to one or more connecting cylinders. More preferably, said connecting arms are located radially relative to the rotary molding platforms.

In another preferred embodiment of the invention, the drive subsystem comprises a toothed crown fixedly attached to the rotary molding platforms, engaged with a pinion and an engine.

In another preferred embodiment of the invention, the drive subsystem comprises one or more secondary motors to provide movement to respective impellers, located on the rotational molding platform.

In another preferred embodiment of the invention, the system comprises a bed subsystem configured to support the whole of said system. More preferably, said bed subsystem comprises, a platform and a bed base with a plurality of support legs, and / or a registration window with a lower access to the system.

DESCRIPTION OF THE FIGURES

For the best understanding of what is described herein, eight figures are attached representing a preferred embodiment of the invention, as well as the different subsystems that comprise it.

Fig. 1 - General perspective view of a preferred embodiment of the compacted ice making system from crushed ice.

Fig. 2 - Perspective view of the crushed ice intake subsystem of the invention, according to a preferred embodiment thereof.

Fig. 3 - Perspective view of the rotational molding platforms of the invention, according to a preferred embodiment thereof.

Fig. 4 - Perspective view of the pressing platform of the invention, according to a preferred embodiment thereof.

Fig. 5 - Perspective view of the compression module of the invention, according to a preferred embodiment thereof.

Fig. 6 - Perspective view of the guide tracks of the inner and outer wheels of the invention, according to a preferred embodiment thereof.

Fig. 7 - Perspective view of the drive subsystem of the invention, according to a preferred embodiment thereof.

Fig. 8 - Perspective view of the bed subsystem of the invention, according to a preferred embodiment thereof.

NUMERICAL REFERENCES USED IN THE FIGURES

In order to help a better understanding of the technical characteristics of the invention, the cited figures are accompanied by a series of numerical references where, for illustrative and non-limiting purposes, the following is represented:

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates, as described in previous sections, to a system for manufacturing compacted ice from crushed ice. A detailed description of the invention, referring to a preferred embodiment thereof, shown in Figures 1-8, is set forth below.

As shown in said figures, the ice compaction system of the present invention, in said preferred embodiment, generally comprises a plurality of subsystems, which define its main functionalities: an intake subsystem (1) (Figure 2) , configured with means to feed the crushed ice system; one or more rotary molding platforms (2) (Figure 3), whose function is to serve as a compaction mold for crushed ice, in addition to transporting crushed ice and compacted ice throughout the production process; a compaction subsystem (3) (Figures 4, 5 and 6) of the crushed ice, comprising, in its preferred embodiment, at least one pressing module (4) (Figure 4), preferably fixed and rigid, against which it will compact the crushed ice, and a compression module (5) (Figure 5) capable of generating compression forces through the movement of one or more pressing cylinders (6); a drive subsystem (7) (Figure 7), which generates the movement for the compaction subsystem (3); and, optionally, a bed subsystem (8) (Figure 8), which structurally supports the whole system. Next, each of the identified subsystems is described.

The intake subsystem (1) (Figure 2) comprises, in its preferred embodiment, an upper intake hopper (9). The function of said upper hopper (9) is to feed crushed ice for rotary molding platforms (2), by at least one hole in the lower region of the upper hopper (9). To replenish the crushed ice of said upper hopper (9), it is possible to use manual or automatic feeding means, in various embodiments of the invention. Also, another function of the upper hopper (9) is to act as a limiting surface of the crushed ice that is on the rotary molding platforms (2), at the beginning of the manufacturing process. Preferably, the upper hopper (9) will not completely cover the upper part of the assembly, in order to leave free space for the pressing module (4), as well as for the extraction of compacted ice outside the system, as it goes forming as part of the manufacturing process.

Figure 3 shows, in a preferred embodiment of the invention, a rotary molding platform (2), whose function is to serve as a mold for crushed ice, in addition to being used as a transport surface for crushed ice and compacted ice, throughout the manufacturing process. Said rotary molding platform (2) preferably comprises a plurality of interchangeable patterns (10), equipped with one or more molding holes (11). The functions of said patterns (10) are, mainly, to be easily replaceable in case of breakdown or maintenance and give the ability to have different technical specifications for the molds of compacted ice, both in size and shape, which are given correspondingly by the size and shape of the molding holes (11), which can adopt a cylindrical design, prism, etc. The said interchangeable patterns (10) are integrated in their respective rotary molding platforms (2), forming the mold of the compacted ice itself. The crushed ice that is on the rotary molding platform (2) will thus fall inside said molding holes (11) and, as it passes through the pressing module (4), will be compacted by the pressure exerted by the pressing cylinders (6) until compacted according to the desired shape.

Figures 5 and 6 show, in a preferred embodiment, the elements of the compression module (5), in addition to the rotary molding platform (2). Said compression module (5) comprises, in a preferred embodiment of the invention: a plurality of wheels (12, 13), preferably distributed as a group of outer wheels (12) and a group of inner wheels (13), guided by corresponding guidance tracks (14, 15) (Figure 6), which together generate the linear movements necessary to compress the crushed ice; a set of lower pistons (16) and pressing cylinders (6), and a set of lower wheel carrier arms (17) and of upper thrust arms (18), which accompany the linear movement of the outer (12) and inner wheels (13), and exert the compression of the crushed ice against the pressing module (4). In addition, said compression module (5) comprises at least one dividing rotary platform (19), whose function is to insulate against the water the lower part of the compaction subsystem (3), which is located between the inner wheels (13) and exterior (12) and the rotary molding platform (2). Between said dividing rotary platform (19) and the rotational molding platform (2), there are, in a preferred embodiment, a series of substantially vertical structural arms (20), which jointly join the elements of said compression module (5).

The rotary molding platform (2) is connected, in said preferred embodiment, by one or more connecting cylinders (21), located in the outer diameter and / or in the inner diameter of the interchangeable patterns (10). Similarly, said connecting cylinders (21) serve as a connecting element for the elements of the compression module (5).

Preferably, the connecting cylinders (21) are connected to the upper thrust arms (18). More preferably, said arms (18) are located radially with respect to the dividing rotary platforms (19), in the free space between the lower part of the rotary molding platform (2) and the upper part of the rotary dividing platform (19) . Said dividing platform (19) consists of holes for receiving and guiding both the vertical structural arms (20) and the lower pistons (16). For its part, the upper thrust arms (18), in addition to serving as a guide and reinforcement for the vertical structural arms (20), are intended to carry and exert pressure on the pressing cylinders (6), the latter being pushed linearly by the upper thrust arms (18), resulting in compaction against the pressing module (4) of the crushed ice, located inside the molding holes (11). Likewise, the upper thrust arms (18) will be lifted by the lower pistons (16), each of them, supported by its lower end on the lower wheel carrier arms (17) that will move linearly, guided by the movement of the outer (12) and inner (13) wheels, when sliding on the guide tracks of the outer (14) and inner (15) wheels of variable section.

Additionally, the function of the lower wheel carrier arms (17) is twofold. On the one hand, in a preferred embodiment, each arm carries an outer wheel (12) and an inner wheel (13), guiding the compression module assembly (5). On the other hand, it acts as lower piston support (16). Said lower wheel carrier arms (17) are radially distributed in the space between the dividing rotary platform (19) and the inner (15) and outer (14) guide tracks.

A preferred embodiment is shown in Figure 6, in which the inner (15) and outer (14) guide tracks, of circular travel and with different heights on which both outer (12) and inner wheels slide (12) are shown. 13). When traveling the space projected by the pressing module (4) on the guide tracks (14, 15), they generate an upward movement in the outer (12) and inner wheels (13), thereby raising the position of the entire set consisting of the outer (12) and inner wheels (13), lower wheel-carrier arms (17), lower pistons (16), upper thrust arms (18) and pressing cylinders (6), exercising the latter, pressing and compacting the crushed ice against the pressing module (4), which will be found inside the molding holes (11).

In Figure 7, the drive subsystem (7) of the invention is shown, whose main function is to generate the main rotation movement of the system, as described above. For this, the drive subsystem (7) comprises, in a preferred embodiment, a toothed crown (22) fixedly fixed to the outside diameter of the rotary molding platforms (2), engaged with a pinion (23) and a motor (24 ) able to spin the whole. Optionally, in said preferred embodiment, the invention has one or more secondary motors (25), capable of providing movement to their respective impellers (26) located on the rotary molding platform (2) whose purpose is to help crushed ice to Do not compact before starting the mechanical compaction process of the invention.

In Figure 8, in a preferred embodiment, the bed subsystem (8) configured to support the whole system is shown. Said bed subsystem (8) preferably comprises a platform (27) and a bed base (28) with a plurality of support legs (29), to rest on the ground or any other bearing surface. Additionally, the subsystem (8) may optionally comprise a registration window (30), which facilitates repairs and replacements in the event of a possible fault, from the bottom of the system.

In this way and as described, the invention provides a crushed ice compaction system capable of forming compacted ice by a continuous process, thereby improving the limitations of the prior art.

Claims (1)

1. - System for the manufacture of compacted ice from crushed ice, comprising: - an intake subsystem (1), configured with means to feed crushed ice and / or flakes into the system; - a compaction subsystem (3) of crushed ice, comprising at least one pressing module (4) against which the crushed ice is compacted, and a compression module (5) equipped with means for generating compression forces at through the movement of one or more pressing cylinders (6); - a drive subsystem (7) of the compaction subsystem (3); where the compaction subsystem (3) also includes one or more rotating platforms (2) of crushed ice molding, arranged between the pressing module (4) and the compression module (5), arranged so that its movement Rotary allows to transport crushed ice and compacted ice during its manufacture; and where the drive subsystem (7) is equipped with means to propitiate the rotation of the rotating platforms (2) while compacting the crushed ice and characterized in that the compression module (5) comprises a plurality of wheels (12, 13) connected to the compression cylinders (6), and guided by one or more corresponding guide tracks (14, 15), so that The passage of the wheels (12, 13) through the guide tracks generates the linear movements of said compression cylinders (6). 2. - System according to the preceding claim, wherein the intake subsystem comprises an upper intake hopper (9), equipped with manual or automatic ice feeding means. 3. - System according to any of the preceding claims, wherein the rotary molding platforms (2) comprise one or more interchangeable patterns (10) equipped with one or more molding holes (11). 4. - System according to any of the preceding claims, wherein the wheels (12, 13) are distributed as a group of outer wheels (12) and a group of inner wheels (13) in the compression module (5). 5. - System according to any of the preceding claims, wherein the guide tracks (14, 15) have paths of different heights on which the wheels slide (12, 13). 6. - System according to any of the preceding claims, wherein the compression module (5) also comprises a set of lower pressing pistons (16), and a set of lower arms (17) wheel-holders and arms ( 18) corresponding upper thrusts, which accompany the linear movement of the wheels (12, 13), to compress the crushed ice against the pressing module (4). 7. - System according to any of the preceding claims, wherein the compression module (5) comprises at least one dividing rotary platform (19), configured to insulate against water the part of the compaction subsystem (3) that is located between the wheels (12, 13) and the rotary molding platforms (2). 8. - System according to the preceding claim comprising, between the rotary dividing platform (19) and a rotary molding platform (2), a plurality of substantially vertical structural arms (20). 9. - System according to any of the preceding claims, wherein the rotary molding platform (2) is connected to one or more connecting cylinders (21). 10. - System according to the preceding claim, wherein the connecting cylinders (21) are located radially in relation to the rotary molding platforms (2). 11. - System according to any of the preceding claims, wherein the drive subsystem (7) comprises a toothed crown (22) fixedly fixed to the rotary molding platforms (2), engaged with a pinion (23) and a motor (24 ). 12. - System according to any of the preceding claims, wherein the drive subsystem (7) comprises one or more secondary motors (25) to provide movement to respective impellers (26), located on the rotary molding platform (2). 13. - System according to any of the preceding claims, comprising a bed subsystem (8) configured to support the whole of said system. 14. - System according to the preceding claim, wherein the bed subsystem (8) comprises, a platform (27) and a bed base (28) with a plurality of legs (29) support, and / or a registration window (30) with a lower access to the system.