CN209951063U - Ice cake and ice slush adding mechanism - Google Patents

Abstract

The utility model discloses an ice cake and slush adding mechanism, which comprises an ice making assembly, a demoulding assembly, a storage assembly and an ice cake processing assembly, wherein the ice making assembly comprises an ice cake module and a freezing component, the ice cake module is suitable for containing liquid, the freezing component is suitable for freezing the liquid contained in the ice cake module so as to enable the liquid to form ice cakes, the demoulding assembly is suitable for separating the ice cake contained in the ice cake module from the ice cake module, the storage assembly is arranged below the demoulding assembly so as to be suitable for receiving the ice cakes demoulded by the demoulding assembly, the lower end of the storage assembly is provided with a first ice cake outlet and a second ice cake outlet, the lower end of the ice cake processing assembly is provided with a discharge port, the ice cake processing assembly comprises a crushing component and a material pushing component, and the ice cake and slush adding mechanism does not need manual participation in the processes of ice cake manufacturing, storage and later stage to the ice cake, the labor cost is low, and unmanned operation is facilitated.

Description

Ice cake and ice slush adding mechanism

Technical Field

The utility model relates to an automatic fresh fruit beverage machine technical field especially relates to an add ice cube ice-slush mechanism.

Background

The automatic fresh fruit beverage machine is a modern science and technology product, adopts the machine of professional simulation artificial intelligence, need not manual operation and service, sets for the procedure after, just self-cleaning and carry fruit, automatic peeling and denucleate juice extraction and custom collocation ice sand salad, automatic dress cup and remove to specific self-extracting position, automatic order storage etc. make the high-efficient swift custom of user collocation fresh fruit juice intelligent beverage equipment. Wherein, in order to meet the iced taste of partial consumers, the automatic fresh fruit beverage machine is designed with the function of automatically adding ice cubes and ice slush. The traditional ice maker, the ice storage device and the ice and sand grinding machine are single-function operation machines and need manual adding, collecting and other work, so that in order to achieve an intelligent unmanned system of the automatic fresh fruit beverage maker, an integral mechanism for automatically adding ice and sand is designed in the machine.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a mechanism for adding ice cubes and ice slush, which does not need artificial participation in the manufacturing, storage and later period of ice cubes and is favorable for unmanned operation.

The purpose of the utility model is realized by adopting the following technical scheme:

a mechanism for adding ice cubes and making ice slush comprises an ice making assembly, a demolding assembly, a storage assembly and an ice cube processing assembly, wherein the ice making assembly comprises an ice cube mold and a freezing assembly, the ice cube mold is suitable for containing liquid, the freezing assembly is suitable for freezing the liquid contained in the ice cube mold to enable the liquid to form ice cubes, the demolding assembly is suitable for separating the ice cubes contained in the ice cube mold from the ice cube mold, the storage assembly is arranged below the demolding assembly and is suitable for receiving the ice cubes demolded by the demolding assembly, a first ice cube outlet and a second ice cube outlet are formed in the lower end of the storage assembly, a discharge hole is formed in the lower end of the ice cube processing assembly, the ice cube processing assembly comprises a crushing assembly and a material pushing assembly, the crushing assembly is arranged at the lower end of the first ice cube outlet, the crushing assembly is suitable for crushing the ice cubes discharged by the first ice cube outlet to enable the ice cubes to form ice slush, and discharging the ice slush from the discharge hole, wherein the material pushing component is arranged at the lower end of the second ice block outlet so as to be suitable for pushing the ice blocks discharged from the second ice block outlet to the discharge hole.

Further, the ice-making assembly includes a water injection plate disposed at an upper end of the ice cube module, the water injection plate being adapted to deliver liquid into the ice cube module.

Further, the ice making assembly further comprises a water injection plate guide rail and an electric push rod arranged on the water injection plate guide rail, the water injection plate is arranged on the water injection plate guide rail and is in sliding connection with the water injection plate guide rail, one end of the electric push rod is fixedly connected with the water injection plate so as to be suitable for driving the water injection plate to move back and forth along the length direction of the water injection plate guide rail.

Further, the ice cube adding and ice slush mechanism further comprises a controller, and the electric push rod is electrically connected with the controller so as to be suitable for the controller to control the expansion amount of the electric push rod.

Further, install optical fiber sensor on the water injection board guide rail, optical fiber sensor with the controller electricity is connected, when the water injection board moves to the optical fiber sensor position, optical fiber sensor is suitable for the positional information who detects the water injection board to with positional information transmission to in the controller, the controller will control the electric push rod stops work.

Further, the freezing part comprises a compressor, a condenser and an evaporator mounted on the ice cube module, and the compressor and the condenser are connected with the evaporator through pipelines.

Further, drawing of patterns subassembly includes driving motor and sets up the heater block of driving motor right-hand member, the ice cube mould install in on the driving motor main shaft, driving motor is suitable for the drive the upset of ice cube mould, so that ice cube mould bottom with the heater block butt, work as ice cube mould bottom with during the heater block butt, the heater block is suitable for right the ice cube mould heating to make the ice cube mould hold the ice-cube and be heated and melt in the ice cube mould, with the ice cube mould separation, and fall into the setting and be in the drawing of patterns subassembly lower extreme in the storage component.

Further, the storage assembly comprises an ice storage device, the ice storage device is suitable for storing ice cubes demoulded by the demoulding assembly, and the first ice cube outlet and the second ice cube outlet are formed in the bottom end of the ice storage device.

Furthermore, a first ice storage hopper and a second ice storage hopper are formed at the bottom end of the ice storage device, the first ice outlet is formed at the bottom end of the first ice storage hopper, and the second ice outlet is formed at the bottom end of the second ice storage hopper.

Further, the storage component further comprises an ice-removing drainage plate, the ice-removing drainage plate is arranged between the ice storage device and the demolding component, so that ice cubes after demolding by the demolding component fall onto the ice-removing drainage plate, and the ice-removing drainage plate is suitable for shunting the ice cubes to enable the ice cubes to flow into the first ice storage device hopper and the second ice storage device hopper.

Further, the surface of the deicing drainage plate is provided with a baffle.

Furthermore, the crushing part comprises a crushing motor, an ice and sand conveying pipe and a spiral feeding knife arranged on the crushing motor, the spiral feeding knife is arranged in the ice and sand conveying pipe, an ice block inlet which is correspondingly arranged with the first ice block outlet is formed in the ice and sand conveying pipe, so that the spiral feeding knife is suitable for discharging ice blocks from the first ice block outlet and enabling the ice blocks to enter the ice and sand conveying pipe through the ice block inlet, and after the ice blocks enter the ice and sand conveying pipe, the crushing motor is suitable for driving the spiral feeding knife to rotate so as to crush the ice blocks, so that the ice blocks form ice and sand, and the ice and sand is conveyed to the discharge port along the ice and sand conveying pipe to be discharged.

Furthermore, the material pushing component comprises a material pushing push rod and a push rod push block arranged on the material pushing push rod, when the ice cubes fall from the second ice cube outlet, the material pushing push rod is suitable for driving the push rod push block to move towards the direction of the discharge hole, and the push rod push block is abutted against the ice cubes to push the ice cubes to the discharge hole.

Further, the ice cake processing assembly further comprises a discharge plate, the discharge port is formed in the discharge plate, the crushing component and the material pushing component are mounted on the discharge plate, and the crushing component and the material pushing component are symmetrically arranged with the discharge port as the center.

Furthermore, an icing channel straight pipe is arranged at the lower end of the discharging plate, the icing channel straight pipe is installed at the discharging port, and the icing channel straight pipe is suitable for guiding ice blocks or ice slush discharged from the discharging port into a cup placed at the lower end of the icing channel straight pipe.

Furthermore, the discharge plate is provided with two guide plates, and the two guide plates are arranged on two sides of the material pushing component, so that the material pushing component can push the ice blocks into the discharge hole along the guide plates.

Further, a counting sensor is installed at the discharge port and electrically connected with the control end of the material pushing component, the counting sensor is suitable for calculating the quantity information of ice cubes pushed into the discharge port by the material pushing component and transmitting the quantity information of the ice cubes to the control end of the material pushing component, and the control end of the material pushing component receives the quantity information of the ice cubes transmitted by the counting sensor and controls the material pushing component to work or stop working.

Furthermore, the ice cube filling mechanism further comprises a recovery assembly, the recovery assembly comprises a water tank and a water injection backflow plate arranged at the lower end of the ice making assembly, the water injection backflow plate is suitable for guiding liquid overflowing from the edge of the ice cube mold into the water tank when the ice cube mold is filled with the liquid, and the water tank is suitable for storing the liquid guided by the water injection backflow plate.

Furthermore, a drainage plate is formed on the surface of the water injection backflow plate.

Further, the recovery assembly further comprises an overflow backflow plate arranged on the side face of the storage assembly, and when liquid overflows from the ice cube module, the overflow backflow plate is suitable for guiding the liquid overflowing from the ice cube module to the water injection backflow plate and flowing into the water tank through the water injection backflow plate for storage.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the set ice cube module is matched with the freezing assembly, so that ice cubes can be made while a machine is used, the ice cubes do not need to be prepared in advance, and the use is convenient; the demolding assembly is arranged to separate the ice blocks from the ice block mold, and a user does not need to manually separate the ice blocks from the ice block mold, so that the labor cost is effectively reduced, in addition, the storage assembly is arranged at the lower end of the demolding assembly to facilitate the storage of the ice blocks after the ice blocks are manufactured, manual tightening is not needed, meanwhile, the first ice block outlet and the second ice block outlet are formed at the lower end of the storage assembly, the crushing component is arranged at the lower end of the first ice block outlet, the material pushing component is arranged at the lower end of the second ice block outlet, so that the ice blocks can be discharged from the discharge port by starting the material pushing component when the ice blocks are needed, or the crushing component is started to crush the ice blocks discharged from the first ice block outlet when the ice blocks are needed, so that the ice blocks form ice slush and are discharged from the discharge port, the ice blocks are not needed to be manually placed at the crushing component and the material pushing, in addition, no manual participation is needed in the process of manufacturing and adding the ice cake and the ice slush, so that the manpower resource is reduced, and the unmanned operation is realized.

Drawings

FIG. 1 is a schematic structural view of the ice-adding ice-slush mechanism of the present invention;

FIG. 2 is an exploded view of the ice and slush mechanism of the present invention;

FIG. 3 is a schematic structural view of an ice making assembly of the ice cake and smoothie adding mechanism of the present invention;

FIG. 4 is a schematic structural view of the demolding assembly of the ice-adding and ice-slush mechanism of the present invention;

FIG. 5 is a schematic structural view of the ice adding ice and slush mechanism storage assembly of the present invention;

FIG. 6 is a schematic structural view of an ice processing assembly of the ice adding and slush mechanism of the present invention;

FIG. 7 is a schematic structural view of a crushing unit of the ice adding and slush mechanism of the present invention;

fig. 8 is a schematic structural diagram of the pushing component of the ice-cube ice-slush adding mechanism of the present invention.

In the figure: 10. an ice making assembly; 11. an ice cube module; 12. a freezing component; 121. a compressor; 122. a condenser; 123. an evaporator; 13. a water injection plate; 14. a water injection plate guide rail; 15. an electric push rod; 16. an optical fiber sensor; 20. a demolding component; 21. a drive motor; 22. a heating member; 30. a storage component; 31. an ice storage device; 311. a first ice storage hopper; 312. a second ice storage hopper; 32. a de-icing drainage plate; 40. an ice handling assembly; 41. a pulverizing member; 411. a grinding motor; 412. a frozen sand conveying pipe; 4121. an ice block inlet; 413. a spiral feeding knife; 42. a material pushing member; 421. a material pushing push rod; 422. a push rod push block; 43. a discharge plate; 431. a discharge port; 432. adding an ice channel straight pipe; 433. a baffle; 434. a counting sensor; 50. a recovery assembly; 51. a water tank; 52. a water injection reflux plate; 53. and an overflow reflux plate.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

As shown in fig. 1 to 8, an ice cake and slush adding mechanism includes an ice making assembly 10, a demolding assembly 20, a storage assembly 30 and an ice cake processing assembly 40, where the ice making assembly 10 includes an ice cake mold 11 and a freezing assembly 12, the ice cake mold 11 is adapted to contain a liquid, the freezing assembly 12 is adapted to freeze the liquid contained in the ice cake mold 11 so that the liquid forms ice cakes, the demolding assembly 20 is adapted to contain ice cakes from the ice cake mold 11, the storage assembly 30 is disposed below the demolding assembly 20 and is adapted to receive the ice cakes demolded by the demolding assembly 20, the storage assembly 30 has a first ice cake outlet and a second ice cake outlet at a lower end thereof, the ice cake processing assembly 40 has a discharge outlet 431 at a lower end thereof, the crushing assembly 40 includes a crushing member 41 and a material pushing member 42, the crushing member 41 is disposed at a lower end of the first ice cake outlet, the crushing member 41 is adapted to crush the ice cakes discharged through the first ice cake outlet so that the ice cakes are formed, and discharges the smoothie from the discharge hole 431, and the push member 42 is provided at a lower end of the second ice cube outlet to be adapted to push the ice cubes discharged through the second ice cube outlet to the discharge hole 431.

When the ice cube storage device works, liquid is filled into the ice cube module 11, then the freezing part 12 is started to freeze the liquid contained in the ice cube module 11, so that the liquid contained in the ice cube module 11 is cooled to form ice cubes, and at the moment, the ice cubes are separated from the ice cube module 11 by the demolding assembly 20, so that the ice cubes fall into the storage assembly 30 arranged at the lower end of the demolding assembly 20 to be stored; when the ice slush is required, the crushing member 41 operates to crush the ice cubes discharged from the first ice cube outlet so that the ice cubes form the ice slush and discharge the ice slush from the discharge hole 431; when ice is needed, the pushing member 42 operates to push the ice discharged from the second ice outlet to the discharging hole 431 and discharge the ice through the discharging hole 431.

The arranged ice cube module 11 is matched with the freezing assembly, so that ice cubes can be manufactured while a machine is used, the ice cubes do not need to be prepared in advance, and the use is convenient; the demolding assembly 20 is arranged to separate ice blocks from the ice block mold 11, and the ice blocks are separated from the ice block mold 11 without manual work of a user, so that labor cost is effectively reduced, in addition, the storage assembly 30 is arranged to facilitate storage of the ice blocks after manufacture, meanwhile, a first ice block outlet and a second ice block outlet are formed in the lower end of the storage assembly 30, the crushing component 41 is arranged at the lower end of the first ice block outlet, and the pushing component 42 is arranged at the lower end of the second ice block outlet, so that when ice blocks are needed, the pushing component 42 is started to discharge the ice blocks discharged from the second ice block outlet from the discharge hole 431, or when ice blocks are needed, the crushing component 41 is started to crush the ice blocks discharged from the first ice block outlet, so that the ice blocks form ice slush and are discharged from the discharge hole 431, and the user can conveniently select to add the ice blocks or.

The ice making assembly 10 includes a water injection plate 13 disposed at an upper end of the ice cube mold 11, the water injection plate 13 being adapted to deliver liquid into the ice cube mold 11. The water injection plate 13 communicates with an external water path through a water pipe in the application.

In operation, the water injection plate 13 sprays liquid uniformly on the ice cube molds 11, and then the freezing assembly freezes the ice cube molds 11, so that the liquid on the ice cube molds 11 is frozen to form ice cubes. For guaranteeing that the liquid that sprays in to ice-cube mould 11 in every recess is even, correspond every recess on the water injection board 13 and seted up a plurality of hole for water sprayings to make water injection board 13 spray the liquid in the recess can be even, the phenomenon that the ice-cube is not of uniform size appears when avoiding freezing.

The ice making assembly 10 further comprises a water injection plate guide rail 14 and an electric push rod 15 mounted on the water injection plate guide rail 14, the water injection plate 13 is mounted on the water injection plate guide rail 14 and is in sliding connection with the water injection plate guide rail 14, and one end of the electric push rod 15 is fixedly connected with the water injection plate 13 and is suitable for driving the water injection plate 13 to reciprocate along the length direction of the water injection plate guide rail 14.

The during operation, electric push rod 15 drive water injection board 13 moves to ice-cube mould 11 top along water injection board guide rail 14 to make water injection board 13 evenly spray liquid to ice-cube mould 11 on, after spraying the completion, electric rod drive water injection board 13 moves away from ice-cube mould 11 top along water injection board guide rail 14, when avoiding freezing subassembly to ice-cube mould 11 to freeze, the liquid that holds in the water injection board 13 simultaneously freezes, lead to holding in the water injection board 13 that liquid freezes.

Specifically, the ice adding and ice slush mechanism further comprises a controller, and the electric push rod 15 is electrically connected with the controller so as to be suitable for the controller to control the expansion amount of the electric push rod 15.

During operation, the controller will control the flexible volume of electric push rod 15 to make water injection board 13 can follow water injection board guide rail 14 and move to ice cube mould 11 top, avoid electric push rod 15 flexible volume too big or undersize during operation, water injection board 13 is not placed ice cube mould 11 in completely, and partial liquid sprays around the machine when leading to water injection board 13 to spray, and is clean inconvenient, and leads to other parts of machine impaired easily.

And when the water injection plate 13 moves to the position of the optical fiber sensor 16, the optical fiber sensor 16 is suitable for detecting the position information of the water injection plate 13 and transmitting the position information to the controller, and the controller controls the electric push rod 15 to stop working.

By installing the optical fiber sensor 16 on the water injection plate guide rail 14, the water injection plate 13 is prevented from falling from the tail end of the water injection plate guide rail 14 or leading to the breakage of a water pipe connecting the water injection plate 13 with an external water source due to insufficient length when moving along the water injection plate guide rail 14.

The freezing part 12 includes a compressor 121, a condenser 122, and an evaporator 123 mounted on the ice cube module 11, and the compressor 121 and the condenser 122 are connected to the evaporator 123 through pipes.

Be arranged in holding liquid to ice-cube mould 11 through setting up compressor 121, condenser 122 and evaporimeter 123 and freeze, freezing effect is good, and liquid can freeze fast in the ice-cube mould 11 and form the ice-cube, and the person of facilitating the use in time uses.

The demoulding assembly 20 comprises a driving motor 21 and a heating component 22 arranged at the right end of the driving motor 21, the ice cube die 11 is installed on a spindle of the driving motor 21, the driving motor 21 is suitable for driving the ice cube die 11 to turn over so that the bottom of the ice cube die 11 is abutted to the heating component 22, and when the bottom of the ice cube die 11 is abutted to the heating component 22, the heating component 22 is suitable for heating the ice cube die 11 so that ice cubes contained in the ice cube die 11 are heated and melted to be separated from the ice cube die 11 and fall into a storage assembly 30 arranged at the lower end of the demoulding assembly 20.

During operation, driving motor 21 is suitable for drive ice cube mould 11 and overturns 180 degrees, and ice cube mould 11 bottom and heating element 22 butt, ice-cube will be towards the storage component direction in the ice cube mould 11 this moment, heating element 22 heats ice cube mould 11, make ice-cube and ice cube mould 11 laminating part be heated and melt, ice-cube and ice cube mould 11 separation, the ice-cube will fall from ice cube mould 11 under the effect of gravity, and fall into storage component 30 and store, heat ice cube mould 11 through setting up heating element 22, so that the ice-cube separates from ice cube mould 11, cooperate driving motor 21 drive ice cube mould 11 to overturn 180 degrees again, make the ice-cube fall from ice cube mould 11 under the effect of gravity, need not artifical drawing of patterns, and manpower cost is reduced. In the present application, the heating component 22 is an electronic defroster, and can be replaced by a heating device such as an electric heating plate.

Specifically, the storage assembly 30 includes an ice storage 31, the ice storage 31 is adapted to store the ice cubes ejected from the ejection assembly 20, and a first ice outlet and a second ice outlet are formed at a bottom end of the ice storage 31.

During the use, the ice-cube after the drawing of patterns will be stored in the ice storage device 31 of falling under the effect of gravity, make things convenient for the automatic collection of shaping back ice-cube, need not the manual work and collect, the cost of using manpower sparingly, simultaneously, improved work efficiency.

More specifically, in order to facilitate the discharge of the ice cubes in the ice storage 31 from the first ice cube outlet or the second ice cube outlet, a first ice storage bin 311 and a second ice storage bin 312 are formed at the bottom end of the ice storage 31 to store the ice cubes respectively when the ice cubes enter the ice storage 31, the ice cubes in the first ice storage bin 311 can be discharged through the first ice cube outlet, and the ice cubes in the second ice storage bin 31 can be discharged through the second ice cube outlet by opening the first ice cube outlet at the bottom end of the first ice storage bin 311 and opening the second ice storage bin 312 at the bottom end of the second ice storage bin 312, and meanwhile, the phenomenon that the ice cubes are accumulated in the first ice cube outlet or the second ice cube outlet and the other ice cube outlet does not contain the ice cubes can be avoided by adopting the arrangement of the two ice storage bins 31.

The storage assembly 30 further comprises an ice-shedding flow-guiding plate 32, the ice-shedding flow-guiding plate 32 is disposed between the ice storage device 31 and the demolding assembly 20, so as to be suitable for ice cubes demolded by the demolding assembly 20 to fall onto the ice-shedding flow-guiding plate 32, and the ice-shedding flow-guiding plate 32 is suitable for shunting the ice cubes, so that the ice cubes flow into the first ice storage hopper 311 and the second ice storage hopper 312.

In operation, the ice-cube that falls from drawing of patterns subassembly 20 will fall on deicing drainage plate 32, and shunt via deicing drainage plate 32, make in the ice-cube mould 11 the ice-cube can evenly flow into first ice storage ware fill 311 and second ice storage ware fill 312, it is too big to avoid storing ice-cube quantity difference in first ice storage ware fill 311 and the second ice storage ware fill 312, the phenomenon that no ice-cube is available appears when leading to the user to need ice-cube or ice-slush, when falling on deicing drainage plate 32 for avoiding the ice-cube simultaneously, the ice-cube receives to strike violently, lead to the ice-cube to take place to fragment, still be provided with the rubber pad on the deicing drainage plate 32, with the impact that receives when reducing the ice-cube and falling on deicing drainage plate 32, the rubber pad need adopt food level rubber to make, in order to guarantee that food is healthy. In addition, the deicing flow guide plate 32 can be arranged in a V shape in the application.

In addition, when the ice blocks fall on the deicing drainage plate 32, the ice blocks fly out from the side of the deicing drainage plate 32, which causes waste and easily causes potential safety hazards, so that the baffle is arranged on the surface of the deicing drainage plate 32 to block the ice blocks when the ice blocks fall on the deicing drainage plate 32, and prevent the ice blocks from flying out of the deicing drainage plate 32.

The crushing unit 41 includes a crushing motor 411, an ice and sand conveying pipe 412 and a spiral feeding blade 413 installed on the crushing motor 411, the spiral feeding blade 413 is disposed in the ice and sand conveying pipe 412, the ice and sand conveying pipe 412 is provided with an ice block inlet 4121 corresponding to the first ice block outlet, so that the ice blocks discharged from the first ice block outlet enter the ice and sand conveying pipe 412 through the ice block inlet 4121, after the ice blocks enter the ice and sand conveying pipe 412, the crushing motor 411 is adapted to drive the spiral feeding blade 413 to rotate to crush the ice blocks, so that the ice blocks form ice and sand, and the ice and sand is conveyed to the discharge port 431 along the ice and sand conveying pipe 412 to be discharged.

In operation, ice cubes are discharged from the first ice cube outlet and fall into the ice cube inlet 4121 corresponding to the first ice cube outlet, the crushing motor 411 is started, the spiral feeding blade 413 is driven by the crushing motor 411 to rotate so as to crush the ice cubes falling into the ice slush conveying pipe 412, the ice cubes falling from the first ice cube outlet fall between the first ice cube outlet and the ice cube inlet 4121 and do not completely enter the ice slush conveying pipe 412 because the spiral feeding blade 413 is arranged in the ice slush conveying pipe 412, the bottom of the ice cubes is in contact with the spiral feeding blade 413, the spiral feeding blade 413 scrapes the bottom of the ice cubes to form ice shavings, and the spiral feeding blade 413 is in a spiral shape, so the scraped ice shavings move to the tail end of the ice slush conveying pipe 412 along with the spiral feeding blade 413 and are discharged from the discharge port 431. The amount of the slush added in this application is set by calculating the time (or the number of turns) for debugging and controlling the operation of the pulverizing motor 411.

The spiral feeding knife 413 is adopted to crush ice blocks, the crushing effect is good, and the ice blocks are discharged from the first ice block outlet, the ice blocks are clamped between the first ice block outlet and the ice block inlet 4121 and do not completely fall into the ice and sand conveying pipe 412, so that the spiral feeding knife 413 can be distributed to cut and crush the ice blocks, the ice blocks can be prevented from completely falling into the ice and sand conveying pipe 412 to be crushed, the phenomenon that the spiral feeding knife 413 is clamped or damaged due to overlarge ice block particles is caused, the service life of the crushing motor 411 and the spiral feeding knife 413 is prolonged, meanwhile, the spiral feeding knife 413 is spirally arranged, so that the cut ice blocks can move to the tail end of the ice and sand conveying pipe 412 along with the spiral feeding knife 413, namely, the position of the discharge hole 431 is located, and a pushing mechanism is not required to be additionally arranged to push the crushed ice blocks into the.

The pushing component 42 comprises a pushing push rod 421 and a push rod push block 422 mounted on the pushing push rod 421, when the ice cubes fall from the second ice cube outlet, the pushing push rod 421 is adapted to drive the push rod push block 422 to move towards the discharging port 431, and the push rod push block 422 abuts against the ice cubes to push the ice cubes to the discharging port 431.

When the ice cube discharging device works, ice cubes fall from the second ice cube outlet, the pushing push rod 421 drives the push rod push block 422 to move towards the direction of the discharging port 431 until the push rod push block 422 abuts against the ice cubes and drives the ice cubes to move towards the direction of the discharging port 431 synchronously, when the ice cubes are removed from the lower end of the second ice cube outlet, the cylinder rod of the pushing push rod 421 moves to the lower end of the second ice cube outlet to block the second ice cube outlet so as to prevent the ice cubes from falling out of the second ice cube outlet, when the ice cubes fall from the discharging port 431, the pushing push rod 421 contracts to drive the push rod push block 422 to move towards the direction far away from the discharging port 431 until the cylinder rod of the pushing push rod 421 moves away from the lower end of the second ice cube outlet, the ice cubes fall from.

The pushing push rod 421 is arranged to push the ice cubes to the discharge hole 431 for adding, so that the automation of adding the ice cubes is realized, and meanwhile, when the pushing push rod 421 pushes the ice cubes away from the second ice cube outlet, the cylinder rod of the pushing push rod 421 blocks the second ice cube inlet 4121 to prevent the ice cubes from falling from the second ice cube outlet, so that a blocking component is not required to be additionally installed at the second ice cube outlet to block the second ice cube outlet, and the manufacturing cost of the device is reduced.

The ice processing assembly 40 further includes a discharging plate 43, the discharging hole 431 is formed in the discharging plate 43, the crushing member 41 and the pushing member 42 are mounted on the discharging plate 43, and the crushing member 41 and the pushing member 42 are symmetrically arranged with the discharging hole 431 as the center.

The crushing component 41 and the pushing component 42 are symmetrically arranged by taking the discharging port 431 as the center, so that the ice and sand crushed by the crushing component 41 and the ice cubes pushed by the pushing component 42 can enter the discharging port 431 and fall into a cup placed at the lower end of the discharging port 431 from the discharging port 431, a user can add the ice and sand at the same position without moving the cup, and the use is convenient.

The lower end of the discharging plate 43 is provided with an icing channel straight pipe 432, the icing channel straight pipe 432 is installed at the discharging hole 431, and the icing channel straight pipe 432 is adapted to guide ice cubes or slush discharged from the discharging hole 431 into a cup placed at the lower end of the icing channel straight pipe 432.

The discharging plate 43 is provided with two guiding plates 433, and the two guiding plates 433 are disposed at two sides of the pushing component 42, so that the pushing component 42 can push the ice cubes into the discharging hole 431 along the guiding plates 433.

By arranging the two guide plates 433 on the discharging plate 43, guidance can be provided for the ice cubes in the process that the material pushing component 42 pushes the ice cubes, the ice cubes are prevented from sliding out of the edge of the material pushing component 42 in the moving process, and the ice cubes can be moved to the discharging hole 431.

The discharge port 431 is provided with a counting sensor 434, the counting sensor 434 is electrically connected with the control end of the pushing component 42, the counting sensor 434 is suitable for calculating the quantity information of the ice cubes pushed into the discharge port 431 by the pushing component 42 and transmitting the quantity information of the ice cubes to the control end of the pushing component 42, and the control end of the pushing component 42 receives the quantity information of the ice cubes transmitted by the counting sensor 434 and controls the pushing component 42 to work or stop working.

When the ice cube pushing device is in operation, the material pushing component 42 pushes ice cubes into the material outlet 431, the counting sensor 434 installed at the material outlet 431 detects the number of ice cubes falling from the material outlet 431 and transmits the information of the number of ice cubes to the control end of the material pushing component 42, the control end of the material pushing component 42 receives the information of the number of ice cubes transmitted by the counting sensor 434 and feeds the information of the number of ice cubes back to the external display for reference of a user, and the user controls the material pushing component 42 to operate or stop operating through the control end as required to determine the number of the added ice cubes.

The ice cube filling and ice slush mechanism further comprises a recovery assembly 50, the recovery assembly 50 comprises a water tank 51 and a water injection backflow plate 52 arranged at the lower end of the ice making assembly 10, the water injection backflow plate 52 is suitable for guiding liquid overflowing from the edge of the ice cube mold 11 into the water tank 51 when the ice cube mold 11 is filled with the liquid, and the water tank 51 is suitable for storing the liquid guided by the water injection backflow plate 52.

Guide through setting up water injection backward flow board 52 with the liquid that overflows from ice-cube mould 11 edge when to filling liquid, prevent that liquid from splashing all around, it is clean inconvenient, avoid liquid to flow into the organism inside simultaneously, cause the organism electric leakage, lead to the potential safety hazard, flow out from water injection backward flow board 52 side simultaneously for avoiding liquid, the event is formed with the drainage board on water injection backward flow board 52 surface, guide for liquid, make liquid can get into and retrieve in the water tank 51, make things convenient for reuse.

More particularly, the recovery assembly 50 further includes an overflow return plate 53 disposed at a side of the storage assembly 30, the overflow return plate 53 being adapted to guide the liquid overflowing from the ice molds 11 toward the water filling return plate 52 and to flow into the water tank 51 via the water filling return plate 52 for storage when the liquid overflows from the ice molds 11.

Through setting up overflow backward flow board 53 with the liquid direction water injection backward flow board 52 that will overflow from ice-cube mould 11, avoid directly falling ice-cube processing assembly 40 from the water that ice-cube mould 11 fell, lead to ice-cube processing assembly 40 impaired, unable normal work avoids taking place the electric leakage phenomenon because of the liquid seepage simultaneously, causes the potential safety hazard.

When the device works, the electric push rod 15 drives the water injection plate 13 to move to the upper end of the ice cube die 11, the water injection plate 13 uniformly sprays liquid on the ice cube die 11, after the liquid is filled in each groove on the ice cube die 11, the electric push rod 15 drives the water injection plate 13 to move away from the ice cube die 11 so as to avoid freezing the water injection plate 13 at the same time when the ice cube die 11 is frozen in the next step, so that the liquid in the water injection plate 13 is frozen, then the ice cube die 11 is frozen by the freezing part 12 formed by the compressor 121, the condenser 122 and the evaporator 123 arranged on the ice cube die 11, low-temperature gas is sprayed on the ice cube die 11 through the evaporator 123 so as to freeze the liquid contained in the ice cube die 11, after ice making is finished, the driving motor 21 connected with the ice cube die 11 drives the ice cube die 11 to rotate 180 degrees so that the bottom of the ice cube die 11 is abutted to the electronic defroster, the ice cube die 11 is heated by the electronic defroster, so that the contact part of the ice cubes and the ice cube mold 11 is dissolved, the ice cubes are separated from the ice cube mold 11, and because the ice cube mold 11 rotates 180 degrees, the ice cubes contained in the ice cube mold 11 fall off from the ice cube mold 11 under the action of gravity and fall onto the ice-shedding flow guide plate 32 arranged below the demolding assembly 20, and are distributed to the first ice storage hopper 311 and the second ice storage hopper 312 by the ice-shedding flow guide plate 32, so as to avoid the excessive difference of the number of the ice cubes stored in the first ice storage hopper 311 and the second ice storage hopper 312, when ice sand is needed, the crushing motor 411 drives the spiral feeding knife 413 to rotate so as to crush the ice cubes falling into the ice sand conveying pipe 412, the crushed ice sand is conveyed to the discharge port 431 along with the spiral feeding knife 413, and when ice cubes are needed, the material pushing rod 421 drives the pushing rod 422 to move towards the discharge port 431 to abut against the discharge port 431 and drive the ice cubes to move towards the discharge port 431 synchronously, and discharging the ice blocks from the discharging port 431 to realize the addition of the ice blocks or the ice slush.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (20)

1. The utility model provides a mechanism for adding ice cubes and smoothie which characterized in that: the ice making assembly comprises an ice cube mold and a freezing component, the ice cube mold is suitable for containing liquid, the freezing component is suitable for freezing the liquid contained in the ice cube mold to enable the liquid to form ice cubes, the demolding component is suitable for separating the ice cubes contained in the ice cube mold from the ice cube mold, the storage component is arranged below the demolding component and is suitable for receiving the ice cubes after demolding through the demolding component, a first ice cube outlet and a second ice cube outlet are formed in the lower end of the storage component, a discharge hole is formed in the lower end of the ice cube processing component, the ice cube processing component comprises a crushing component and a material pushing component, the crushing component is arranged at the lower end of the first ice cube outlet, and the crushing component is suitable for crushing the ice cubes discharged through the first ice cube outlet to enable the ice cubes to form ice slush, and discharging the ice slush from the discharge hole, wherein the material pushing component is arranged at the lower end of the second ice block outlet so as to be suitable for pushing the ice blocks discharged from the second ice block outlet to the discharge hole.

2. The ice cube smoothie mechanism of claim 1, wherein: the ice-making assembly includes a water injection plate disposed at an upper end of the ice cube module, the water injection plate being adapted to deliver liquid into the ice cube module.

3. The ice cube smoothie mechanism of claim 2, wherein: the ice making assembly further comprises a water injection plate guide rail and an electric push rod arranged on the water injection plate guide rail, the water injection plate is arranged on the water injection plate guide rail and is in sliding connection with the water injection plate guide rail, one end of the electric push rod is fixedly connected with the water injection plate so as to be suitable for driving the water injection plate to follow the water injection plate guide rail to reciprocate in the length direction.

4. A mechanism for adding ice cubes and smoothie as in claim 3, wherein: the electric push rod is electrically connected with the controller so as to be suitable for the controller to control the telescopic amount of the electric push rod.

5. The ice cube smoothie mechanism of claim 4, wherein: the water injection plate is characterized in that an optical fiber sensor is installed on the guide rail of the water injection plate and electrically connected with the controller, when the water injection plate moves to the position of the optical fiber sensor, the optical fiber sensor is suitable for detecting the position information of the water injection plate and transmitting the position information to the controller, and the controller controls the electric push rod to stop working.

6. The ice cube smoothie mechanism of claim 1, wherein: the freezing part comprises a compressor, a condenser and an evaporator arranged on the ice cube module, and the compressor and the condenser are connected with the evaporator through pipelines.

7. The ice cube smoothie mechanism of claim 1, wherein: the drawing of patterns subassembly includes driving motor and sets up the heater block of driving motor right-hand member, the ice cube mould install in on the driving motor main shaft, driving motor is suitable for the drive the ice cube mould upset, so that ice cube mould bottom with the heater block butt, work as ice cube mould bottom with during the heater block butt, the heater block is suitable for right the ice cube mould heating to it melts to hold the ice-cube in the ice cube mould to be heated, with the ice cube mould separation, and fall into the setting and be in the drawing of patterns subassembly lower extreme in the storage component.

8. The ice cube smoothie mechanism of claim 1, wherein: the storage assembly comprises an ice storage device, the ice storage device is suitable for storing ice cubes demoulded by the demoulding assembly, and the first ice cube outlet and the second ice cube outlet are formed in the bottom end of the ice storage device.

9. The ice cube smoothie mechanism of claim 8, wherein: the ice storage device comprises an ice storage device body, a first ice storage device hopper and a second ice storage device hopper, wherein the first ice storage device hopper and the second ice storage device hopper are formed at the bottom end of the ice storage device body, the first ice storage device hopper is arranged at the bottom end of the ice storage device body, and the second ice storage device hopper is arranged at the bottom end of the ice storage device body.

10. The ice cube smoothie mechanism of claim 9, wherein: the storage component further comprises an ice removal drainage plate, the ice removal drainage plate is arranged between the ice storage device and the demolding component, so that ice cubes after demolding of the demolding component fall onto the ice removal drainage plate, the ice removal drainage plate is suitable for shunting the ice cubes, and the ice cubes flow into the first ice storage device hopper and the second ice storage device hopper.

11. The ice cube smoothie mechanism of claim 10, wherein: and the surface of the deicing drainage plate is provided with a baffle.

12. The ice cube smoothie mechanism of claim 1, wherein: the crushing part comprises a crushing motor, a slush conveying pipe and a spiral feeding knife arranged on the crushing motor, the spiral feeding knife is arranged in the slush conveying pipe, an ice block inlet which is correspondingly arranged with the first ice block outlet is formed in the slush conveying pipe, so that the spiral feeding knife can be suitable for being used for discharging ice blocks from the first ice block outlet, the ice blocks enter the slush conveying pipe, when the ice blocks enter the slush conveying pipe, the crushing motor is suitable for driving the spiral feeding knife to rotate so as to crush the ice blocks, so that the ice blocks form slush, and the slush is conveyed to the discharge port to be discharged.

13. The ice cube smoothie mechanism of claim 1, wherein: the material pushing component comprises a material pushing push rod and a push rod push block arranged on the material pushing push rod, when ice cubes fall down from the second ice cube outlet, the material pushing push rod is suitable for driving the push rod push block to move towards the direction of the discharge hole, and the push rod push block is abutted against the ice cubes to push the ice cubes to the discharge hole.

14. The ice cube smoothie mechanism of claim 1, wherein: the ice cake processing assembly further comprises a discharge plate, the discharge hole is formed in the discharge plate, the crushing component and the material pushing component are installed on the discharge plate, and the crushing component and the material pushing component are symmetrically arranged with the discharge hole as the center.

15. A ice cube smoothie mechanism as in claim 14, wherein: the ice adding device is characterized in that an ice adding channel straight pipe is arranged at the lower end of the discharging plate and is installed at the discharging port, and the ice adding channel straight pipe is suitable for guiding ice blocks or ice slush discharged from the discharging port into a cup arranged at the lower end of the ice adding channel straight pipe.

16. A ice cube smoothie mechanism as in claim 14, wherein: the discharging plate is provided with two guide plates, and the two guide plates are arranged on the two sides of the material pushing component to be suitable for the material pushing component to push the ice blocks along the guide plates into the discharging port.

17. The ice cube smoothie mechanism of claim 1, wherein: the counting sensor is installed at the discharge port, the counting sensor is electrically connected with the control end of the material pushing component, the counting sensor is suitable for calculating the quantity information of ice cubes at the discharge port, the quantity information of the ice cubes is transmitted to the control end of the material pushing component, the control end of the material pushing component receives the quantity information of the ice cubes transmitted by the counting sensor and controls the material pushing component to work or stop working.

18. The ice cube smoothie mechanism of claim 1, wherein: still including retrieving the subassembly, it includes the water tank and sets up to retrieve the subassembly the water injection backward flow board of ice-making subassembly lower extreme, water injection backward flow board is suitable for will be when ice-cube mould filling liquid from the liquid guide-in of ice-cube mould edge overflow in the water tank, the water tank is suitable for to the leading-in liquid of water injection backward flow board is stored.

19. A ice cube smoothie mechanism as in claim 18, wherein: and a drainage plate is formed on the surface of the water injection backflow plate.

20. A ice cube smoothie mechanism as in claim 18, wherein: the recovery assembly further comprises an overflow backflow plate arranged on the side face of the storage assembly, and when liquid overflows from the ice cube module, the overflow backflow plate is suitable for guiding the liquid overflowing from the ice cube module to the water injection backflow plate and enabling the liquid to flow into the water tank through the water injection backflow plate for storage.

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