CN114642369B - Food manufacturing method, food processor and storage medium - Google Patents

Abstract

The invention discloses a food preparation method, which comprises the following steps: cooling and preserving: starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so that the temperature of the food materials in the accommodating cavity is lower than the target temperature; pulping: crushing the food materials in the accommodating cavity, and mixing the crushed food materials with water in the accommodating cavity, wherein the pulping step is performed after the cooling and fresh-keeping step. The invention also discloses a food processor and a computer readable storage medium, which achieve the effect of improving the freshness of the soybean milk.

Description

Food manufacturing method, food processor and storage medium

Technical Field

The present invention relates to the technical field of food processors, and more particularly, to a food preparation method, a food processor, and a computer-readable storage medium.

Background

With the promotion of consumption, consumers have increasingly higher requirements on the taste of soymilk for soymilk machine. In order to improve the convenience of the soymilk machine, a plurality of soymilk machines are provided with the function of reserving soymilk making. The soymilk machine can automatically add beans and soak beans according to the reservation information of the user so as to finish the preparation of soymilk in reserved time.

However, in a region where the weather is hot, the soybean soaking process generally needs to last for a long time, so that the freshness of the soybean is easily lowered, and the phenomenon of insufficient freshness of the soybean milk occurs. Thus, the conventional soymilk machine has the defect of low freshness of soymilk.

The foregoing is provided merely for the purpose of facilitating understanding of the technical solutions of the present invention and is not intended to represent an admission that the foregoing is prior art.

Disclosure of Invention

The invention mainly aims to provide a food manufacturing method, a food processor and a computer readable storage medium, which aim to achieve the effect of improving the freshness of soybean milk.

To achieve the above object, the present invention provides a food preparation method comprising the steps of:

cooling and preserving: starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so that the temperature of the food materials in the accommodating cavity is lower than the target temperature;

pulping: crushing the food materials in the accommodating cavity, and mixing the crushed food materials with water in the accommodating cavity, wherein the pulping step is performed after the cooling and fresh-keeping step.

Optionally, the cooling and preserving step is performed when a preset condition is satisfied, where the preset condition includes at least one of the following: :

Receiving a control instruction for starting a cooling and fresh-keeping function;

detecting that food to be processed exists in the accommodating cavity;

detecting that the food material to be processed in the accommodating cavity is infiltrated;

the food processor begins to perform a soaking step;

the food processor starts to execute or has completed the food material washing step;

the food processor receives reservation setting;

the temperature in the accommodating cavity and/or the ambient temperature in the space where the food processor is located are/is greater than or equal to a preset temperature.

Optionally, the food preparation method further comprises:

soaking: injecting target amount of water into the accommodating cavity to soak the food in the accommodating cavity, wherein the cooling and fresh-keeping step is executed simultaneously with the soaking step, or the soaking step is executed before the cooling and fresh-keeping step, or the soaking step is executed after the cooling and fresh-keeping step.

Optionally, the food preparation method further comprises:

and a draining step of draining water in the accommodating chamber, wherein the draining step is performed before the pulping step and after the soaking step.

Optionally, the food preparation method further comprises a food material cleaning step, wherein the food material cleaning step comprises the following steps:

Injecting water into the accommodating cavity to enable the water level to be higher than or equal to the cleaning water level;

stirring the accommodating cavity;

and after stirring for preset times or preset time, discharging water in the accommodating cavity, wherein the food material cleaning step is executed before the cooling and fresh-keeping step, or is executed simultaneously with the cooling and fresh-keeping step, or is executed between the cooling and fresh-keeping step and the pulping step.

Optionally, the cooling and fresh-keeping step includes:

detecting a temperature within the containment chamber;

when the temperature in the accommodating cavity is higher than the first temperature, starting the refrigerating device;

and closing the refrigerating device when the temperature in the accommodating cavity is less than or equal to a second temperature and/or the operation time of the refrigerating device reaches a preset time, wherein the second temperature is less than or equal to the first temperature.

Optionally, the target temperature is 30 ℃ or less; and/or the cooling and fresh-keeping steps comprise:

and starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so as to enable the temperature of the food materials in the accommodating cavity to be 0-15 ℃.

Optionally, the cooling and fresh-keeping step includes:

detecting a temperature within the containment chamber;

determining the operation power of the refrigerating device according to the temperature in the accommodating cavity, wherein the higher the temperature in the accommodating cavity is, the higher the operation power is;

and controlling the refrigerating device to refrigerate according to the running power.

Optionally, the pulping step includes:

crushing, namely beating food materials to be processed through a crushing device; and

a water adding step of injecting water into the accommodating cavity; wherein the method comprises the steps of

The pulverizing step is prior to the water adding step; or alternatively

The pulverizing step is subsequent to the water adding step; or alternatively

The crushing step and the water adding step are performed simultaneously; or alternatively

The water adding step comprises a first water adding step and a second water adding step, and the crushing step is performed on the

And the first water adding step and the second water adding step are performed simultaneously, or the crushing step and the first water adding step are performed simultaneously, or the crushing step and the second water adding step are performed simultaneously, wherein the first water adding step and the second water adding step are used for injecting water into the accommodating cavity for a plurality of times.

Optionally, the food processor further comprises a pulp discharging valve device and a cup body, the accommodating cavity is formed in the cup body, the cup body further comprises a discharging hole communicated with the accommodating cavity, and the pulp discharging valve device is installed in the cup body and connected with the discharging hole; the food preparation method further comprises the following steps:

And (3) pulp discharging: and controlling the pulp discharging valve device to perform pulp discharging operation, wherein the pulp discharging step is performed after the pulping step.

Optionally, the food preparation method further comprises a reservation step, the reservation step comprising:

receiving reservation setting information;

determining the execution time points of the cooling and fresh-keeping step and the pulping step according to the reservation setting information, and executing the cooling and fresh-keeping step and the pulping step when the current time point reaches the execution time point.

In addition, to achieve the above object, the present invention also provides a food processor including: the food processor further comprises a memory, a processor and a control program of the food processor, wherein the control program of the food processor is stored in the memory and can run on the processor, and the control program of the food processor realizes the steps of the food preparation method when being executed by the processor.

In addition, in order to achieve the above object, the present invention also provides a computer-readable storage medium having stored thereon a control program of a food processor, which when executed by a processor, implements the steps of the food preparation method as described above.

The embodiment of the invention provides a food manufacturing method, a food processor and a computer readable storage medium, which comprises the following steps of: starting the refrigerating device, refrigerating the accommodating cavity through the refrigerating device so that the temperature of food materials in the accommodating cavity is lower than the target temperature, and then performing pulping: crushing the food material in the accommodating cavity, and mixing the crushed food material with water in the accommodating cavity. The freshness of the food materials to be processed can be maintained through the cooling and fresh-keeping steps, so that the effect of improving the freshness of the soybean milk manufactured by the soybean milk machine is achieved.

Drawings

FIG. 1 is a schematic diagram of a terminal structure of a hardware operating environment according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of a food preparation method according to an embodiment of the present invention;

FIG. 3 is a schematic flow chart of another embodiment of the food preparation method of the present invention;

FIG. 4 is a schematic view of a first embodiment of the food processor of the present invention;

fig. 5 is a front view showing a part of the construction of the food processor of fig. 4 in which the pulp discharge valve device of the first embodiment is installed;

FIG. 6 is a cross-sectional view of the structure of FIG. 7;

FIG. 7 is a cross-sectional view at A-A in FIG. 8;

FIG. 8 is an exploded view of the structure of FIG. 7; in the figure, the valve cover and the valve seat are in a separated state;

FIG. 9 is an exploded view of the structure of FIG. 7; in the figure, the valve cover and the valve core are separated from the valve seat;

FIG. 10 is an exploded view of the slurry discharge valve apparatus of FIG. 7;

fig. 11 is a perspective view showing a part of the structure of a food processor equipped with a pulp discharge valve device of the second embodiment of the present invention;

FIG. 12 is a cross-sectional view of the structure of FIG. 11;

fig. 13 is an exploded view of the structure of fig. 11;

FIG. 14 is a front view of the discharge valve apparatus of FIG. 11;

FIG. 15 is a cross-sectional view at A-A in FIG. 14;

FIG. 16 is an exploded view of the discharge valve assembly of FIG. 11;

FIG. 17 is a sectional view showing a construction of a food processor of the present invention equipped with a pulp discharge valve device according to a third embodiment;

FIG. 18 is a schematic view of the structural valve body of FIG. 17 in a removed state;

FIG. 19 is a schematic view showing the construction of a first bracket in the slurry valve apparatus of FIG. 17;

FIG. 20 is a schematic perspective view of a valve body of the slurry discharge valve apparatus of FIG. 17;

FIG. 21 is an exploded view of the valve body of FIG. 20;

FIG. 22 is a schematic cross-sectional view of a food processor of the present invention equipped with a pulp discharge valve device of a fourth embodiment;

FIG. 23 is a perspective view of the structure of FIG. 22 with the valve body and second bracket in an extracted state;

FIG. 24 is a schematic cross-sectional structural view of the structure of FIG. 23;

FIG. 25 is a schematic view of the structure of FIG. 24, with the valve body and second bracket in a removed state, from a further perspective;

FIG. 26 is a schematic cross-sectional structural view of the structure of FIG. 25;

FIG. 27 is an exploded view of the valve body of FIG. 22;

FIG. 28 is a schematic view showing a first modified structure of a pulp discharge valve device according to the fourth embodiment;

FIG. 29 is an exploded view of the structure of FIG. 28;

FIG. 30 is a cross-sectional view showing a second modified structure of the pulp discharge valve device and a cup assembly structure of the food processor according to the fourth embodiment of the present invention;

FIG. 31 is an exploded view of a part of the structure of the pulp discharge valve device of FIG. 30;

FIG. 32 is a cross-sectional view showing a third modified structure of the pulp discharge valve device and a cup assembly structure of the food processor according to the fourth embodiment of the present invention;

FIG. 33 is an exploded view of a part of the structure of the pulp discharge valve device of FIG. 32;

FIG. 34 is a cross-sectional view showing a fourth modified structure of the pulp discharge valve device and a cup assembly structure of the food processor according to the fourth embodiment of the present invention;

Fig. 35 is an exploded view of a part of the structure of the pulp discharge valve device in fig. 34.

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

As shown in fig. 1, the terminal may include: a processor 1001, such as a CPU, a network interface 1004, a user interface 1003, a memory 1005, a communication bus 1002. Wherein the communication bus 1002 is used to enable connected communication between these components. The user interface 1003 may include a Display (Display), an input unit such as keys, a touch screen, etc., and the optional user interface 1003 may also include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 1005 may be a high-speed RAM memory or a stable memory (non-volatile memory), such as a disk memory. The memory 1005 may also optionally be a storage device separate from the processor 1001 described above.

It will be appreciated by those skilled in the art that the terminal structure shown in fig. 1 is not limiting of the terminal and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components.

As shown in fig. 1, an operating system, a network communication module, a user interface module, and a control program of the food processor may be included in the memory 1005 as one type of computer storage medium.

In the terminal shown in fig. 1, the network interface 1004 is mainly used for connecting to a background server and performing data communication with the background server; the processor 1001 may be configured to call a control program of the food processor stored in the memory 1005 and perform the following operations:

cooling and preserving: starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so that the temperature of the food materials in the accommodating cavity is lower than the target temperature;

pulping: crushing the food materials in the accommodating cavity, and mixing the crushed food materials with water in the accommodating cavity, wherein the pulping step is performed after the cooling and fresh-keeping step.

Referring to fig. 4, the food processor includes a receiving chamber 31, a cooling device 35 for cooling food to be processed in the receiving chamber 31, and a cooling device 40 communicating with the receiving chamber 31 and injecting a cooling liquid into the receiving chamber 31.

In some applications, the blending device 40 includes a water tank 40A, a water pump 40B, and a waterway 40C. The waterway 40C may be a water pipe. The water inlet of the water pump 40B is communicated with the water tank 40A through the water path 40C, and the water outlet of the water pump 40B is communicated with the accommodating cavity 31 through the water path 40C. The water pump 40B, when in operation, pumps water from the water tank into the receiving chamber 31.

Alternatively, the water inlet of the water pump 40B may also communicate with the external water source (not shown) through the waterway 40C.

Optionally, the food processor further comprises a comminuting device 50, the comminuting device 50 extending into the receiving chamber 31 and being located above the cooling device 35.

Referring to fig. 5 to 10 in combination, in the first embodiment, the slurry discharging valve device 60 includes a valve body 61, the valve body 61 includes a valve body housing, the valve body housing includes a valve seat 62, a valve cover 63, a material discharging pipe 67 and a valve core 64, the valve seat 62 is provided with a feeding hole 621, the feeding hole 621 can be in butt joint communication with the material discharging hole 311, wherein the valve seat 62 is mounted on an outer wall surface of the cup assembly 30, specifically, a screw column is disposed on an outer wall surface of the cup assembly 30, and a screw hole is disposed on the valve seat 62, and the valve seat 62 is fixedly connected with the heating plate by screwing the screw column into the screw hole. The valve cover 63 is provided with a slurry discharging hole 631, and the valve cover 63 can be covered with the valve seat 62 and is matched with the valve seat 62 and the inner part of the valve cover 63 to form a material discharging channel communicated with the material feeding hole 621 and the slurry discharging hole 631 and a mounting hole 632 communicated with the material discharging channel. Valve element 64 extends into the discharge channel at least partially through mounting hole 632, and valve element 64 is movable relative to valve cover 63 and valve seat 62 to control the on-off of the discharge channel;

Wherein the valve cover 63 and the valve seat 62 are detachably connected, and/or the valve element 64 may be separated from the valve cover 63 and connected to the valve seat 62, or the valve element 64 may be separated from the valve seat 62 and connected to the valve cover 63, or the valve element 64 may be provided separately from both the valve cover 63 and the valve seat 62.

In this embodiment, the valve cover 63 and the valve seat 62 are both substantially square frame structures, and the valve cover 63 and the valve seat 62 are substantially square box-shaped after being covered, however, in other embodiments, the valve cover 63 and the valve seat 62 may be cylindrical or shaped. The specific shapes of the discharge hole 311, the feed hole 621 and the slurry discharge hole 631 are not limited, and in this embodiment, all three are circular holes. The feed hole 621 and the discharge hole 631 are located on two opposite surfaces of the square box constituted by the valve cover 63 and the valve seat 62, and the mounting hole 632 is located on the surface of the square box between the feed hole 621 and the discharge hole 631. In addition to the portion of the valve core 64 extending into the discharge channel, the exposed portion of the valve core 64 can be observed from the mounting hole 632, and the valve core 64 can be turned to control the on-off of the discharge channel, or pulled into the discharge channel to block or withdraw from the discharge channel to make it conductive. Wherein the valve element 64 is constrained by the valve cover 63 and the valve seat 62 together when the valve cover 63 is closed to the valve seat 62, and the valve element 64 is capable of being released from the constraint of the valve cover 63 and the valve seat 62 when the valve cover 63 is released from the valve seat 62. The discharge pipe 67 may be integrally formed with the valve cover 63, or may be fastened to the valve cover 63, or may be glued to the valve cover, so that the discharge pipe 67 extends downward a distance to better guide fluid into the receiving cup assembly 20.

In this embodiment, the valve cover 63 is designed to be detachably connected with the valve seat 62, so that the valve cover 63 can be separated from the valve seat 62, so that the valve cover 63 can be removed from the valve seat 62 after the slurry discharge valve device 60 is used for a long time, and the valve core 64, the valve cover 63 and the valve seat 62 can be cleaned and flushed, so that food residues can be prevented from staying, the possibility of bacteria breeding is reduced, and the health and safety of food is improved.

The valve seat 62 and the valve cover 63 are detachably connected, wherein the detachment refers to detachment without any tool or installation with any tool on the premise that the self structure of the slurry discharging valve device 60 is not damaged when cleaning is needed, so that the detachment and cleaning of a user are convenient, and the use sanitation of the food processor is maintained; also included are tools that are easy to disassemble and assemble using common tools without the need for specialized tools or specialized personnel directed disassembly. In some possible implementations of the removable connection of the valve cover 63 and the valve seat 62, one of the valve cover 63 and the valve seat 62 is fitted with a magnetic member 66a, and the other is fitted with a magnetic member 66b, and the valve cover 63 and the valve seat 62 are connected by magnetic attraction of the magnetic member 66a and the magnetic member 66 b. Wherein both the magnetic member 66a and the magnetic attraction member 66b may be magnets, or one may be a magnet and the other a soft magnetic material such as a ferrous material. The magnetic element 66a and the magnetic element 66b may be square or round, and may be glued, inlaid or injection molded into the valve cover 63 or the valve seat 62 through pre-embedding, the magnetic element 66a and the magnetic element 66b are preferably mounted on opposite surfaces of the valve seat 62 and the valve cover 63, specifically, mounting grooves are formed on opposite surfaces of the valve cover 63 and the valve seat 62, and the magnetic element 66a and the magnetic element 66b are correspondingly inlaid in the mounting grooves. And the magnetic pieces 66a or the magnetic pieces 66b are embedded and arranged at four corners of the opposite surfaces of the valve seat 62 and the valve cover 63, so that the valve cover 63 and the valve seat 62 are firmly connected, and the valve core 64 can be taken out only by taking off the valve cover 63 through external force when the valve cover 63 is required to be cleaned and disassembled.

In some possible solutions for the removable connection of the valve cover 63 and the valve seat 62, one of the valve cover 63 and the valve seat 62 is provided with a buckle, the other of the two is provided with a buckle position, and the valve cover 63 and the valve seat 62 are clamped by the buckle and the buckle position in a mutually matched manner. The scheme may be that a buckle is connected to a side wall surface of the valve cover 63, and a buckling position is formed on a corresponding side wall surface of the valve seat 62 in a concave manner, and a combination of the buckle and the buckling position may be arranged in pairs and respectively located on two opposite sides of the valve seat 62 and the valve cover 63. Through such setting, easy dismounting, simultaneously, also can reduce cost. Of course, in other embodiments, the combination of the magnetic member 66a and the magnetic member 66b, plus the combination of the snap and the snap position, may be provided.

The above is a solution of the detachable connection of the valve seat 62 and the valve cover 63 in the case where they can be separately provided, and in other embodiments, the valve seat 62 and the valve cover 63 can be separately provided in a manner that the valve seat 62 and the valve cover 63 are connected by a screw or a bolt.

Referring to fig. 7 to 10 again, in the present embodiment, the valve core 64 includes a valve body section 642 and a driving section 643, the valve body section 642 is cylindrical and rotatable in the discharge channel, the valve body section 642 is provided with a valve hole 641 communicating the feeding hole 621 and the slurry discharging hole 631 in the on position, and the driving section 643 extends from the mounting hole 632. The valve core 64 of this embodiment is movable in the discharge channel in a rotating manner, and the driving section 643 extends out from the mounting hole 632, so that the valve hole 641 is communicated with the fluid channel by rotating the driving section 643 and then driving the valve body section 642 to rotate. In the case where the valve core 64 is automatically driven to rotate by electricity, the driving structure may be connected to the driving section 643 to drive the valve core 64, and in the above-mentioned scheme that the valve core 64 is drawn into the discharge channel to block or withdraw from the discharge channel to make it conductive, the valve body section 642 of the valve core 64 may be configured as a flat door structure, and the driving section 643 is drawn outwards to open the fluid channel, or is inserted inwards into the fluid channel to close the fluid channel.

The present embodiment preferably automatically controls the rotation of valve element 64, wherein slurry discharge valve apparatus 60 further includes a drive motor 68, the drive shaft of drive motor 68 being drivingly connected to drive segment 643. The driving motor 68 may be mounted to the outer wall of the cup assembly 30, and the present embodiment preferably mounts the driving motor 68 to the valve seat 62, and in particular, may form a motor bracket at a side of the valve seat 62, to which the driving motor 68 is fixedly coupled by screws. In order to facilitate the driving connection between the driving motor 68 and the valve core 64, in this embodiment, the driving section 643 is provided with a slot 645, and the driving shaft of the driving motor 68 is inserted into the slot 645, where the slot 645 is an open slot penetrating in the radial direction of the driving section 643, and the valve core 64 can be conveniently adjusted to clamp the driving shaft of the motor into the slot 645 during installation.

Further, a rotation lever 681 is further mounted on the driving shaft of the driving motor 68, and a first position sensor 682 and a second position sensor 683 are respectively mounted on the rotation lever 681 and the valve seat 62, which are engaged with each other. The first position sensing element 682 and the second position sensing element 683 may be a combination of a bump and a micro switch, or a combination of a magnet and a reed switch, and may precisely control the valve core 64 to stay in the on position and the off position by controlling the on/off position of the driving motor 68 during rotation through the calibrated position, i.e. in the pulp discharging step, the valve core 64 is driven to rotate by controlling the driving motor 68 to open the discharging channel.

Further, the valve body 61 further comprises a sealing sleeve 65 sleeved outside the valve body section 642, the sealing sleeve 65 is provided with a via hole adapted to the valve hole 641, and the via hole is communicated with the valve hole 641 when the valve body section 642 is in a conducting position; seal cartridge 65 is fixed relative to valve seat 62 and/or valve cover 63, and valve body section 642 is rotatably coupled to seal cartridge 65. Specifically, the outer wall of the sealing sleeve 65 is convexly provided with a positioning convex rib 651, the valve seat 62 and/or the valve cover 63 is provided with a positioning groove 622, and the positioning convex rib 651 is clamped into the positioning groove 622. The seal cover 65 can be made of food-grade silica gel, and can seal the valve body 61 through the arrangement of the seal cover 65, so that fluid leakage is avoided. During the cleaning process, the sealing sleeve 65 may be removed along with the valve cartridge 64.

The valve body section 642 is close to one end of the mounting hole 632 and is also convexly provided with a limiting part 644, the limiting ring is stopped by the inner wall of the discharge channel in the direction that the valve body section 642 is separated from the mounting hole 632, the limiting part 644 can be of an annular structure or of a bump structure, and the valve core 64 can be prevented from shaking in the axial direction in the rotating process by the design of the limiting part 644.

In summary, in the first embodiment of the slurry discharging valve device 60, the valve seat 62 and the valve cover 63 in the valve body housing are designed to be detachably connected, so that the valve core 64 can be taken out for cleaning, and the electronic components such as the driving motor 68 are not affected in the disassembling process, so that the whole cleaning process is convenient. Referring to fig. 11 to 16 in combination, in the second embodiment of the slurry discharging valve device 70, the slurry discharging valve device 70 includes a valve body 71, the valve body 71 includes a valve body housing, the valve body housing includes a valve seat 72, a valve core 73 and a slurry discharging pipe 76, the valve seat 72 is provided with a feeding hole 721 and a slurry discharging hole 722, a material discharging channel communicating the feeding hole 721 and the slurry discharging hole 722 is formed in the valve seat 72, the valve seat 72 is further provided with a mounting hole 723, the mounting hole 723 is communicated with the material discharging channel, the valve core 73 extends into the material discharging channel at least partially through the mounting hole 723 and can move relative to the valve seat 72 to control the on-off of the material discharging channel, the slurry discharging pipe 76 can be integrally formed with the valve seat 72, or the separated structure is connected with the valve seat 72 in a clamping manner or an adhesive manner, the slurry discharging pipe 76 extends downwards for a certain distance, and fluid can be better guided into the receiving cup assembly 20; wherein the valve element 73 can be separated from the valve seat 72 by being pulled away from the mounting hole 723.

The valve seat 72 is of a hollow unitary construction, although the valve seat 72 may be formed by two housings that are snap-fit. The valve seat 72 is connected to the outer wall surface of the cup 31, specifically, a screw column is provided on the outer wall surface of the cup 31, and a screw hole is provided on the valve seat 72, and the valve seat 72 and the cup 31 are connected and fixed by screwing a screw into the screw column and the screw hole. The valve seat 72 may be of square box configuration or cylindrical, or other contoured shape. The specific shapes of the discharge hole 311, the feed hole 721 and the slurry discharge hole 722 are not limited, and in this embodiment, all three are circular holes. The feed hole 721 and the discharge hole 722 are located on two opposite surfaces of the square box, and the mounting hole 723 is located on the surface of the square box between the feed hole 721 and the discharge hole 722. The valve core 73 may be a rotary valve to control the opening and closing of the discharge channel, or a pull valve to enter the discharge channel to block or exit the discharge channel to make it conductive.

In this embodiment, the valve core 73 is designed to be able to be pulled out through the mounting hole 723, so that the valve core 73 can be pulled out directly to be cleaned when cleaning is needed, and the inside of the valve seat 72 can be conveniently flushed out even if the valve core 73 is pulled out, so that food residue in the pulp discharge valve device 70 can be reduced, and the food sanitation and safety can be improved. After the valve element 73 is drawn out of the mounting hole 723, the valve element 73 may be conveniently cleaned, and the valve element 73 may have two types of shapes, that is, a state of being separated from the valve seat 72, or may be: after the valve core 73 is pulled out of the mounting hole 723, the valve core 73 can be hung on the valve seat 72, and only the valve core 73 can be pulled out and cleaned independently.

In this embodiment, the valve core 73 includes a valve body section 732 and a handle section 733, the valve body section 732 is cylindrical and rotatable in the discharge passage, the valve body section 732 is provided with a valve hole 731 that communicates the feed hole 721 and the pulp discharge hole 722 in the on position, and the handle section 733 protrudes from the mounting hole 723. By extending the handle section 733 out of the mounting hole 723. In addition, in the above-mentioned scheme that the valve core 73 is drawn into the discharge channel to block or withdraw from the discharge channel to make it conductive, the valve body section 732 of the valve core 73 may be configured as a flat door body structure, and the fluid channel may be opened by driving the driving section 734 to draw out or insert into the fluid channel to close the fluid channel.

Further, in order to facilitate the extraction of the valve core 73, a pull ring 75 is further connected to the handle section 733, wherein in this embodiment, the mounting hole 723 may be located on the lower surface of the valve seat 72, so that the pull ring 75 may be directly pulled downward from the lower opening of the lower mounting cavity when the valve core 73 is extracted.

In order to improve the tightness, the valve body 71 further comprises a sealing sleeve 74 sleeved on the valve body section 732, the sealing sleeve 74 is provided with a through hole for adapting to the valve hole 731, the sealing sleeve 74 is in interference fit with the valve seat 72, and the sealing sleeve 74 is linked with the valve body section 732 and can be pulled away from the valve seat 72 together with the valve core 73 by a mounting hole 723.

Further, a water stop barb 741 is further provided on the outer wall of the sealing sleeve 74 in a protruding manner, and the water stop barb 741 abuts against the inner wall of the mounting hole 723. In this embodiment, the sealing sleeve 74 is provided with at least one water stop barb 741 at one end close to the handle section 733 and one end far from the handle section 733. The sealing sleeve 74 is surrounded by the water-stopping barb 741, and the water-stopping barb 741 seals the part of the mounting hole 723 of the fluid channel by the arrangement of the water-stopping barb 741, and the inner wall of the mounting hole 723 can be scraped to take food residues out when the valve core 73 is pulled out. In other embodiments, the valve core 73 may be made of elastic material, such as silica gel, rubber, etc., and the water stop hook 741 may be integrally formed on the valve core 73.

In this embodiment, the automatic control valve core 73 preferably rotates, the slurry discharging valve device 70 further includes a driving motor 77 connected to the valve seat 72, one end of the valve body section 732 away from the handle section 733 is connected to a driving section 734, and a driving shaft of the driving motor 77 is in transmission connection with the driving section 734. Wherein slot 735 has been seted up to drive section 734, and the drive shaft of driving motor 77 inserts in slot 735, and wherein slot 735 is the open slot that runs through in the radial of drive section 734, and the case 73 can be comparatively convenient adjustment gesture card in slot 735 with the drive shaft of driving motor 77 when installing.

Further, a sensor 78 for detecting the rotation angle of the valve body 73 is also attached to the valve seat 72.

Referring to fig. 17 to 21 in combination, in the third embodiment, the pulp discharge valve device 80 includes a valve body 81, the valve body 81 includes a valve body housing and a valve core 84, the valve body housing is provided with a feed hole 821 and a pulp discharge hole 831, the valve body housing is formed with a discharge channel communicating with the feed hole 821 and the pulp discharge hole 831 and a mounting hole 822 communicating with the discharge channel, and the valve core 84 extends into the fluid channel from the mounting hole 822 and is movable relative to the valve body housing to control the on-off of the discharge channel. In the present embodiment, the valve body 81 can be detached downward or upward with respect to the cup assembly 30. Here, upward or downward includes not only upward or downward perpendicular to the horizontal direction but also obliquely downward or obliquely upward, for example, obliquely downward or obliquely upward at an angle of 45 degrees or less with respect to the vertical direction. According to the technical scheme, the valve body 81 in the pulp discharging valve device 80 is configured to be capable of being detached from the cup body assembly 30 upwards or downwards, so that when the pulp discharging valve device 80 needs to be cleaned, the valve body 81 can be directly detached, the valve body 81 is cleaned, and meanwhile, the food safety can be improved through cleaning while the cleaning is convenient.

Further, in this embodiment, the pulp discharging valve device 80 further includes a first bracket 87, and the valve body 81 is detachably connected with the first bracket 87, wherein the detachment means that the detachment is performed without any tool or any tool when the cleaning is required, so that the detachment and the cleaning of the user are convenient, and the sanitation of the food processor is maintained; also included are tools that are easy to disassemble and assemble using common tools without the need for specialized tools or specialized personnel directed disassembly. The first bracket 87 may be mounted on an outer wall surface of the cup body 31, specifically, a screw column is disposed on an outer wall surface of the cup body 31 near the discharge hole 311, and a screw hole is disposed on the first bracket 87, and the first bracket 87 and the cup body 31 are connected and fixed by screwing a screw into the screw column and the screw hole. In other embodiments, the first bracket 87 may be mounted on the host housing of the host 10 or other parts of the cup assembly 30, and the fixing manner of the first bracket 87 is not limited to the screw connection manner described above, but may be a snap connection manner, welding or gluing manner, etc.

The first bracket 87 in this embodiment may be manufactured from sheet metal parts by a stamping process or by integral injection molding of plastic material. The valve body housing may be of a hollow unitary construction, although the valve seat 82 may be formed from two shells that are snap fit together. The valve body housing may be of square box configuration or cylindrical, or other contoured shape. The specific shapes of the discharge hole 311, the feed hole 821 and the slurry discharge hole 831 are not limited, and may be round holes or square holes, in this embodiment, all three are round holes. The valve body housing of the present application is generally square box shaped with the feed hole 821 and the discharge hole 831 being located on two opposite surfaces of the square box, and the mounting hole 822 being located on the surface of the square box between the feed hole 821 and the discharge hole 831. The valve core 84 can be rotated to control the opening and closing of the discharge channel, or pulled into the discharge channel to block or withdraw from the discharge channel to make it conductive. In the driving method of the spool 84, the spool 84 may be driven by a non-contact external force, for example, by magnetic force, or the spool 84 may be driven by direct contact.

In this embodiment, the first bracket 87 is disposed on the pulp discharging valve device 80, and the valve body 81 is detachably connected with the first bracket 87, so that when the pulp discharging valve device 80 needs to be cleaned, the valve body 81 can be directly taken down from the first bracket 87, and the valve body 81 can be directly cleaned, so that the cleaning is convenient, and meanwhile, the food safety can be improved through cleaning.

In a possible way of detachably connecting the valve body 81 to the first bracket 87, it is possible that one of the first bracket 87 and the valve body housing is mounted with a magnetic member 88a, and the other is mounted with a magnetic member 88b, and the first bracket 87 and the valve body housing are connected by magnetic attraction of the magnetic member 88a and the magnetic member 88b. Wherein both the magnetic member 88a and the magnetic attraction member 88b may be magnets, or one may be a magnet and the other may be a soft magnetic material such as a ferrous material. The magnetic element 88a and the magnetic element 88b may be in the form of a square block or a round cake, and may be glued, inlaid or injection molded into the first support 87 or the valve body housing by embedding. So through the mode of magnetic adsorption connection, mounting structure is comparatively firm on the one hand, and on the other hand dismouting is also comparatively convenient. It will be appreciated that in other embodiments, the valve body housing may be removably coupled to the first bracket 87, such as by a snap fit connection, or by a screw connection.

Specifically, in some embodiments, the first bracket 87 includes a top plate 871 corresponding to the top wall of the valve body housing, and a side plate 872 adjacent to the top plate 871 and corresponding to the side wall of the valve body housing, i.e., the top plate 871 extends in a generally horizontal direction, and the side plate 872 extends in a generally vertical direction; magnetic pieces 88a and magnetic attraction pieces 88b are provided in pairs between the top plate 871 and the top wall and between the side plate 872 and the side wall. In combination with the above, the first bracket 87 of the present application further includes other plate bodies except the top plate 871 and the side plate 872 described above, and integrally encloses a mounting cavity formed downward in an opening, by such a structural arrangement, when the valve body 81 needs to be taken down, the valve body 81 can be entirely taken down by operating from the opening of the mounting cavity, and when mounting, the two adjacent top plates 871 and side plates 872 can be well positioned for the valve body 81, and it is convenient to realize that the valve body 81 is detached downward in such a dismounting process. It will be appreciated that in other embodiments, when the mounting position of the top plate 871 is set at the bottom of the side plate 872, the first bracket 87 is cooperatively formed with an upwardly opened mounting cavity, so that the valve body 81 as a whole can be removed upwardly, or when the opening of the mounting cavity is slightly inclined upwardly or downwardly, the valve body can be removed upwardly or downwardly in an inclined direction.

Further, the valve body housing includes a valve seat 82 and a valve cover 83 covering the valve seat 82, the valve seat 82 is provided with a feed hole 821, and the valve cover 83 is provided with the slurry discharge hole 831; the valve cover 83 and the valve seat 82 are detachably connected, and the valve core 84 can be separated from the valve body housing when the valve cover 83 is separated from the valve seat 82. In this embodiment, the valve body housing is designed to be openable in addition to the valve body 81 being completely removed for cleaning, the valve seat 82 and the valve cover 83 are designed to be openable, the valve core 84 is restrained by the valve cover 83 and the valve seat 82 together when the valve cover 83 is closed to the valve seat 82, and the valve core 84 is released from the restraint of the valve cover 83 and the valve seat 82 when the valve cover 83 is separated from the valve seat 82, so that the valve core 84 can be removed, and both the interior of the valve body housing and the valve core 84 can be cleaned, thereby improving the cleaning convenience and cleaning effect.

Further, a discharge pipe 85 is further installed on the valve cover 83, and the discharge pipe 85 is communicated with the slurry discharge hole 831. The material discharging pipe 85 can be integrally arranged with the valve cover 83, or in a clamping manner, or in an adhesive structure, and the material discharging pipe 85 extends downwards for a distance, so that fluid can be better guided into the receiving cup assembly. Further, a shroud 873 having an arc-shaped structure is further connected to the first bracket 87, and the shroud 873 is connected to the top plate 871 and encloses a downwardly opening hood structure, wherein the upper portion of the discharge pipe 85 is surrounded by the shroud 873 to provide good protection.

The valve core 84 of this embodiment includes a valve body section 842 and a handle section 844 connected to an end of the valve body section 842, one end of the valve body section 842 away from the handle section 844 is connected with a driving section 843, the valve body section 842 is rotatable in the discharge passage, the valve body section 842 is provided with a valve hole 841 communicating the feed hole 821 and the pulp discharge hole 831 in the on position, and the handle section 844 extends from the mounting hole 822. In the case of electrically and automatically driving the valve element 84 to rotate, the driving structure may be connected to the driving section 843 to drive the valve element 84, and in the above-mentioned scheme that the valve element 84 is drawn into the discharge channel to block or withdraw from the discharge channel so as to be conductive, the valve body section 842 of the valve element 84 may be configured as a flat door structure, and the driving section 843 is pulled out to open the fluid channel, or is inserted into the fluid channel to close the fluid channel. The handle segment 844 extends out from the mounting hole 822, so that the handle segment 844 can be held for operation in the process of dismounting the valve core 84, and the force application is convenient.

In this embodiment, the valve element 84 is preferably automatically controlled to rotate, and the slurry discharging valve device 80 further includes a driving motor 86 connected to the first bracket 87, and a driving shaft of the driving motor 86 is in driving connection with the driving section 843. The driving section 843 is provided with a slot 845, the slot 845 is matched with a driving shaft of the driving motor 86, and the driving shaft is inserted into the slot 845. The driving motor 86 of this example can be installed and fixed on the top plate 871 of the first bracket 87, the driving section 843 is above, the handle section 844 is below, the slot 845 is an open slot penetrating in the radial direction of the driving section 843, when the driving motor is installed in a contraposition mode, the driving motor is in butt joint from bottom to top, through the arrangement that the valve core 84 is provided with the handle section 844 and the driving section 843, in the electric driving process, the driving shaft of the motor can be conveniently adjusted to be clamped into the slot 845 of the valve core 84, and in addition, when the driving motor is cleaned, the operation of the valve core 84 is conveniently taken out through the operation of the handle section 844.

In order to make the valve core 84 not easy to drop out of the valve body casing, in this embodiment, the valve body section 842 is in a ball shape, and a sealing sleeve 824 is respectively sleeved on one side of the valve body section 842 facing the feed hole 821 and one side facing the pulp discharge hole 831, further, in this embodiment, a sealing ring 823 surrounding the feed hole 821 may be embedded on the valve seat 82 of the valve body casing, or a sealing ring surrounding the pulp discharge hole 311 may be embedded on the outer wall surface of the cup assembly 30, and after the pulp discharge valve device is installed, the sealing ring 823 is extruded by the cup 31 and the pulp discharge valve device 80 to ensure the sealing at the feed hole 821 and the pulp discharge hole 311.

Also, in order to realize precise control of the rotation angle of the spool 84 when the drive motor 86 opens and closes the fluid passage, a sensor 89 for detecting the rotation angle of the drive shaft of the drive motor 86 is also mounted on the first bracket 87.

Referring to fig. 22 to 35 in combination, in the fourth embodiment, the pulp discharging valve device 90 is mounted on the outer wall side of the cup 31 of the cup assembly 30, the pulp discharging valve device 90 includes a valve body 91, the valve body 91 includes a valve body housing, the valve body housing has a feed hole 921, a pulp discharging hole 931, a discharge passage communicating the feed hole 921 and the pulp discharging hole 931, and a valve core 94 for controlling the on-off of the discharge passage, the feed hole 921 and the discharge hole 311 can be brought close to each other and in butt communication. While the present embodiment contemplates that the valve body 91 can be laterally withdrawn with respect to the cup assembly 30 for ease of cleaning. The lateral direction includes not only a lateral direction perpendicular to the axial direction of the cup assembly 30, but also a lateral direction inclined to the axial direction of the cup assembly 30, and includes an upward or downward lateral direction inclined to the axial direction of the cup assembly 30 and away from the cup assembly 30. According to the technical scheme, the pulp discharging valve device 90 is designed to be capable of laterally pulling away the valve body 91 relative to the cup body assembly 30, so that the structure of the pulp discharging valve device 90 can be conveniently detached from the cup body assembly 30, the valve body 91 can be conveniently cleaned, residual food material residues are removed, bacteria are reduced, and the food sanitation and safety are improved.

In some embodiments of the present invention, the pulp valve device 90 further comprises a bracket assembly 96, the bracket assembly 96 comprising a first bracket 97 and a second bracket 98, the first bracket 97 being adapted to be mounted to the cup assembly 20 at the discharge aperture 311; the valve body 91 is connected to the second bracket 98, and in some embodiments the valve body 91 and the second bracket 98 may be separable, for example, the valve body 91 and the second bracket 98 may be detachably connected to each other. Wherein, the detachable means that when the cleaning is needed, the self structure of the pulp discharging valve device 90 is not damaged, and the detachable is carried out without any tool or installation by any tool, thereby facilitating the disassembly and cleaning of a user and keeping the use sanitation of the food processor; also included are tools that are easy to disassemble and assemble using common tools without the need for specialized tools or specialized personnel directed disassembly. The second bracket 98 can move along the first bracket 97 so that the feeding hole 921 and the discharging hole 311 are close to each other and are in butt joint communication; or the second support 98 can move along the first support 97 and drive the valve body 91 to move out of the first support 97 together, the valve body 91 can be laterally pulled away from the cup assembly 20 in the process, the movable connection between the first support 97 and the second support 98 adopts a sliding mode, and of course, the first support 97 and the second support 98 can also adopt other movement modes to move out the valve body 91. For example, a relatively swinging manner or a relatively ejecting manner can be adopted.

The first support 97 and the second support 98 are in sliding connection, the first support 97 is used as a structure for bearing and supporting the second support 98 to slide, so that the first support 97 can be in the form of two or more side-by-side guide rails, or in the form of a frame structure, or other structures capable of providing sliding guide for the second support 98, and the second support 98 is used as a tool for carrying the fixed valve body 91. When the first bracket 97 is in the form of a plurality of parallel guide rails, the second bracket 98 should have a slide rail that cooperates with the guide rails, and when the first bracket 97 is in the form of a frame, both sides in the advancing direction of the second bracket 98 can be supported by the first bracket 97. The first bracket 97 may be mounted on an outer wall surface of the cup body 31, specifically, a screw column is disposed on an outer wall surface of the cup body 31 near the discharge hole 311, and a screw hole is disposed on the first bracket 97, and the first bracket 97 is fixedly connected with the refrigeration device by screwing the screw into the screw column and the screw hole. Of course, the manner of fixedly connecting the first bracket 97 to the cup 31 is not limited to the screw connection manner described above, and may be a removable clamping manner or a welding manner.

The specific shapes of the discharge hole 311, the feed hole 921 and the slurry discharge hole 931 are not limited, and may be round holes or square holes, in this embodiment, all three are round holes. The valve core 94 may be implemented by driving the valve core 94 to move by a contactless external force, for example, by driving the valve core 94 to rotate or move linearly by a magnetic driving method, or by driving the valve core 94 to move by a contact external force, for example, by driving the valve core 94 to rotate or move linearly by a motor or a cylinder.

This application technical scheme is through setting up first support 97 and the second support 98 that can mutually slide at pulp discharge valve device 90 to second support 98 can drive valve body 91 and be close to and dock discharge hole 311 along the gliding mode of first support 97, perhaps second support 98 slides and drives valve body 91 and roll-off in the lump after leaving first support 97, and valve body 91 can be taken out by second support 98, so can conveniently wash valve body 91, get rid of remaining food material residue, reduce the production of bacterium, improved food sanitation security.

Further, the first bracket 97 is formed with a chute 971, the second bracket 98 is slidably inserted into the chute 971, and in use, the second bracket 98 can be pulled out in a nearly horizontal manner along a direction indicated by an arrow in fig. 23 to 26, and the valve body 91 can be taken out upwards and separated from the second bracket 98, so that the valve body 91 is convenient to be cleaned. In this embodiment, the first support 97 is preferably a frame structure, four baffles that are sequentially connected enclose to form the chute 971, and the cross-sectional area of the chute 971 is approximately square, and the shape and size of the chute 971 are adapted to the shape and size of the second support 98, so that the first support 97 can form good limit and support on the whole body of the second support 98 in the sliding process of the second support 98, and thus swing is not easy to occur in the sliding process of the second support 98, and the feeding hole 921 on the valve body 91 is more accurately abutted with the discharging hole 311 on the cup assembly 30.

In order to achieve the higher tightness of the valve body 91 when abutting against the discharge hole 311, in some embodiments of the present application, a locking structure is further installed between the first bracket 97 and the second bracket 98, and when the second bracket 98 drives the valve body 91 to approach the discharge hole 311 and the feed hole 921 is in abutting communication with the discharge hole 311, the first bracket 97 and the second bracket 98 are relatively fixed together through the locking structure.

Specifically, referring to fig. 22 to 31, in some possible embodiments of the locking structure, the locking structure includes an elastic buckle 972 disposed on one of the first bracket 97 and the second bracket 98, and a buckle 983 disposed on the other of the first bracket and the second bracket, and when the second bracket 98 drives the valve body 91 to approach the discharge hole 311 and enables the feed hole 921 to be in abutting communication with the discharge hole 311, the buckle 983 is snapped into the elastic buckle 972.

With the locking feature being a snap 983 and resilient catch 972 fit, the present application creates multiple designs of the slurry valve apparatus 90 through structural changes to the bracket assembly 96.

Specifically, referring to fig. 22 to 27, fig. 22 to 27 are schematic views of a first modified structure of the slurry valve device 90 according to the present application in the case of using a locking structure of the buckle 983 and the elastic buckle 972; in this embodiment, the second support 98 includes a support main body 981 and a pressing plate 982 movably connected to the support main body 981, wherein the pressing plate 982 is connected with one of an elastic buckle 972 and a buckle 983, an elastic member 984 is disposed between the support main body 981 and the pressing plate 982, and when the buckle 983 is snapped into the elastic buckle 972, the elastic member 984 provides an elastic force to drive the valve body 91 to approach the discharge hole 311. In this embodiment, the movable connection between the pressing plate 982 and the support main 981 may be a sliding rail and a sliding rail structure formed on the end of the support main 981 and on one side of the pressing plate 982, and a matching structure such as a rib and a bump is disposed on the end of the sliding rail and the sliding rail to prevent the pressing plate 982 from being separated from the support main 981, or the pressing plate 982 and the support main 981 may be connected by a pivot connection on one side and a snap connection on the other side, and the elastic element 984 may be a spring or a shrapnel. The buckle 983 and the elastic buckle 972 are disposed in pairs on two opposite outer wall surfaces of the first bracket 97. During use, the pressing plate 982 is pushed to enable the second bracket 98 to integrally slide along the sliding groove 971 of the first bracket 97, after the feeding hole 921 and the discharging hole 311 are in butt joint, further force is applied to enable the elastic buckle 972 and the buckle 983 to be combined, at this time, the elastic piece 984 between the pressing plate 982 and the bracket main body 981 can be compressed, and then the elastic piece 984 provides elastic force to drive the second bracket 98 to have a trend of approaching the discharging hole 311, so that the valve body 91 can be further pressed and tightly attached to the cup body assembly 20, and the attaching connection structure of the feeding hole 921 and the discharging hole 311 is not easy to loose and generate leakage.

Fig. 28 and 29 are schematic diagrams of a second modified structure of the slurry discharging valve device 90 according to the present application under the scheme that the locking structure is cooperation of the buckling head 983 and the elastic buckle 972, in this embodiment, the first bracket 97 is a frame structure, a chute 971 for accommodating the whole second bracket 98 is formed, specifically, the first bracket 97 includes a cylinder 974 with openings at two ends and a gland 975 movably connected with the cylinder 974, one of the cylinder 974 and the gland 975 is provided with the elastic buckle 972, the other of the cylinder 974 and the gland 975 is provided with the buckling head 983, wherein the movable connection mode of the cylinder 974 and the gland 975 can be a rotary connection mode realized by a pivot on one side of the gland 975, or a mode of connecting the cylinder 974 and the gland 975 by a flexible material, or a hinged mode, the other side of the gland 975 is provided with the buckling head 983, and the outer wall of the cylinder 974 is correspondingly provided with the elastic buckle 972. After the second bracket 98 drives the valve body 91 to slide into the sliding groove 971, the pressing cover 975 covers the cylinder 974, and the fastening head 983 is clamped into the elastic buckle 972, so as to lock the second bracket 98 in the sliding groove 971. In this way, the second bracket 98 and the valve body 91 are stably retained in the first bracket 97, and the second bracket 98 can be further prevented from being released, so that leakage is not easy. Further, an elastic pressing member 977 is also mounted on the surface of the pressing cover 975 facing the chute 971. In the use process, after closing the gland 975, the elastic pressing piece 977 abuts against the second bracket 98 in the chute 971, so that the valve body 91 has a trend of moving towards the discharge hole 311, the feed hole 921 and the discharge hole 311 are tightly attached, when cleaning is needed, the gland 975 is opened in the direction indicated by the arrow in fig. 24 and 25, the second bracket 98 and the valve body 91 can be integrally pulled out, and the valve body 91 is taken down from the second bracket 98 for cleaning.

Fig. 30 to 35 show other possible locking structures of the present application, where the locking structure includes a magnetic member 984 disposed on one of the first bracket 97 and the second bracket 98, and a magnetic member mounted on the other of the two, and the second bracket 98 drives the valve body 91 to approach the discharge hole 311, and makes the magnetic member 984 magnetically attract the magnetic member when the feed hole 921 is in abutting communication with the discharge hole 311. Under the scheme that the locking structure is magnetic attraction, the second bracket 98 comprises a bracket main body 981 and a pressing plate 982 connected with the bracket main body 981, the valve main body 91 is embedded in the bracket main body 981, and one of a magnetic piece 984 and a magnetic attraction piece is arranged on the pressing plate 982. In this embodiment, the pressing plate 982 is fixed at the end of the support main 981, after the support main 981 slides into the slide groove 971 in the first support 97, and after the feeding hole 921 and the discharging hole 311 are abutted, the pressing plate 982 will abut against the end face of the first support 97, and the magnetic member 984 and the magnetic attraction member are disposed in pairs on the opposite wall faces of the first support 97 and the pressing plate 982, wherein both the magnetic member 984 and the magnetic attraction member may be magnets, or one may be a magnet and the other may be a soft magnetic material such as a ferrous material. The magnetic elements and the magnetic attraction elements may be square or round, and may be glued, inlaid or injection molded into the first support 97 or platen 982 by pre-embedding. This embodiment sets up through above-mentioned magnetic connection structure, can be after feed hole 921 and discharge hole 311 butt joint intercommunication, through preventing that the junction of feed hole 921 and discharge hole 311 from leaking to when dismantling the washing, the separation operation is also comparatively convenient.

Referring to fig. 27, in some embodiments, the valve body 91 includes a valve seat 92 and a valve cover 93 covered with the valve seat 92, the valve seat 92 is provided with the feeding hole 921, the valve cover 93 is provided with the slurry discharging hole 931, and the valve seat 92 and the valve cover 93 are covered to form a material discharging channel;

wherein, the valve cover 93 and the valve seat 92 are detachably connected, and/or the valve core 94 can be separated from the valve cover 93 or the valve seat 92 or can be separated from the valve cover 93 and the valve seat 92 simultaneously, wherein, when the valve body 91 is required to be cleaned, the valve body is detached without any tool or any tool, thereby being convenient for a user to detach and clean and keeping the use sanitation of the food processor; also included are tools that are easy to disassemble and assemble using common tools without the need for specialized tools or specialized personnel directed disassembly. When the valve cover 93 and the valve seat 92 are separated when the cleaning operation is needed, at this time, the valve core 94 can be connected to the valve cover 93 and separated from the valve seat 92, or the valve core 94 is connected to the valve seat 92 and separated from the valve cover 93, or the valve core 94 is simultaneously separated from the valve cover 93 or the valve seat 92, which can be convenient for cleaning, in addition, the valve cover 93 and the valve seat 92 can not be separated, and only the valve core 92 is pulled out of the discharging channel, so that the cleaning can be realized. In this embodiment, the valve cover 93 and the valve seat 92 are also provided in a detachable structure in order to further enhance the cleaning convenience, on the basis that the valve body 91 as a whole can be brought out and detached for cleaning by the sliding connection of the second bracket 98 and the first bracket 97. In this application, the valve cover 93 and the valve seat 92 are both substantially square frame structures, and the valve cover 93 and the valve seat 92 are substantially square box-shaped after being covered, however, in other embodiments, the valve cover 93 and the valve seat 92 may be cylindrical or shaped. The feed hole 921 and the pulp discharge hole 931 are located on two opposite surfaces of a square case constituted by the valve cover 93 and the valve seat 92, wherein the valve element 94 is restrained by the valve cover 93 and the valve seat 92 together when the valve cover 93 is closed to the valve seat 92, and the valve element 94 is released from the restraint of the valve cover 93 and/or the valve seat 92 when the valve cover 93 is released from the valve seat 92. Through the mode of designing the valve gap 93 to be detachable connection with the disk seat 92 for the valve gap 93 can separate with the disk seat 92, so can wash the inside of valve gap 93 and disk seat 92 in the use, and the case 94 can be taken out by valve gap 93 and disk seat 92, and the case 94 also can be dismantled and wash, so can avoid food residue to stop, reduce the possibility of breeding the bacterium, improve food health and safety.

Further, the valve cover 93 and the valve seat 92 may be different parts from the second support frame 98, such as the structures shown in fig. 20 to 25, and in other embodiments, the valve cover 93 and the valve seat 92 and the second support frame 98 may be formed as a single body, in which the second support frame 98 includes two portions that are covered with each other, and the two portions form the valve cover 93 and the valve seat 92, respectively, that is, the valve cover 93 and the valve seat 92 are configured to cooperate with the first support frame 97, such as the structure of another embodiment of the slurry discharge valve device 90 shown in fig. 30 and 31, where the support frame body 981 mentioned above is formed as the valve seat 92 and the valve cover 93. Further, no matter the valve body housing of the valve body 91 is integrally or separately arranged with the second support 98, in order to improve the tightness, a sealing ring surrounding the feeding hole 921 may be further embedded on the surface of the valve seat 92 facing the food processor, and when the feeding hole 921 and the discharging hole 311 are in butt joint communication after the valve body 91 is installed in place, the sealing ring 924 is located between the cup 31 and the valve seat 92 in the cup assembly 30.

In this embodiment, the rotation scheme of the contact type electric driving valve core 94 is preferable, wherein when the valve cover 93 is covered with the valve seat 92, the valve seat 92 and the valve cover 93 also cooperate to form a mounting hole 922 communicated with the discharge channel, and the mounting hole 922 is positioned on the surface of the square box between the feeding hole 921 and the slurry discharging hole 931; the pulp discharge valve device 90 further comprises a driving motor 99 connected to the first bracket 97, the valve core 94 comprises a valve body section 942 and a driving section 943 connected with one end of the valve body section 942, the valve body section 942 is rotatable in the discharge channel, the valve body section 942 is provided with a valve hole 941 which is communicated with the feeding hole 921 and the pulp discharge hole 931 when in a conducting position, and a driving shaft of the driving motor 99 is in transmission connection with the driving section 943. The driving motor 99 is electrically connected with the control circuit board 16, and the automatic control of the valve core 94 is realized through the arrangement of the driving motor 99, so that the automatic processing and automatic cleaning process of the food processor can be realized in a matched manner, and the use process is more convenient.

In order to facilitate the driving connection between the driving motor 99 and the valve core 94, in this embodiment, a slot 945 is formed in the driving section 943, and a driving shaft of the driving motor 99 is inserted into the slot 945, wherein the slot 945 is an open slot penetrating through the driving section 943 in the radial direction, and when the valve core 94 is installed, the posture of the driving shaft of the motor can be conveniently adjusted to be inserted into the slot 945. In addition, through the design of the slot 945, the valve body 91 is taken out integrally, the motor of the electric element cannot be influenced, and the assembly and disassembly are more convenient.

In order to facilitate accurate control of the rotation angle of the valve element 94 when closing or opening the discharge passage, a sensor 991 for detecting the rotation angle of the drive shaft is also mounted on the first bracket 97 of the present application.

In this embodiment, the mounting hole 922 is formed on the surface of the square box formed by the valve seat 92 and the valve cover 93 in the vertical direction, the driving section 943 extends from the upper surface, the driving motor 99 is also mounted on the upper portion of the first bracket 97, and further, in order to improve the tightness, the valve body section 942 is in a spherical shape or a cylindrical shape, and a sealing sleeve 923 is disposed between the valve body section 942 and the valve seat 92 and between the valve body section 942 and the valve cover 93.

Further, the valve core 94 further comprises a handle segment 944 connected with the lower end of the valve body segment 942, the handle segment 944 extends out from the opening at the lower end of the mounting hole 922, and the handle segment 944 is arranged, so that on one hand, in the mounting process of the valve core 94, the opening orientation of the slot 945 on the driving segment 943 can be adjusted by driving the handle segment 944, and in the approach process of the valve body 91, the driving shaft can be clamped into the slot 945, so that the butt joint mounting is facilitated.

In order to facilitate the introduction of the fluid into the receiving cup assembly 20, in the structure shown in fig. 18 to 23, a discharge pipe 95 is further installed on the valve cover 93 when the valve cover 93 and the second bracket 98 are separately formed, and the discharge pipe 95 communicates with the slurry discharge hole 931. The material discharging pipe 95 of the valve cover can be integrally arranged with the valve cover 93, or in a clamping mode, or in an adhesive structure, and the material discharging pipe 95 extends downwards for a certain distance, so that fluid can be better guided into the bearing cup assembly 20. Further to facilitate the drawing out of the valve body 91, in all the above embodiments, the bottom of the first bracket 97 may form a relief port 973 through which the supply and discharge pipe 95 passes.

Further, please refer to fig. 30 to 35 again, the present application further obtains a plurality of variants of the slurry discharging valve device 90 with simplified structural design by improving the sealing structure based on the above-mentioned magnetic adsorption connection scheme of the first bracket 97 and the second bracket 98.

Fig. 30 and 31 show a modified embodiment of the slurry discharging valve device 90 with a simplified structural design, in which the sealing sleeve 95 in this embodiment is modified to include a first tube 951 and a second tube 952 connected to each other, the first tube 951 is located in the discharging channel and contains the valve body 942, and the second tube 952 is extended from the slurry discharging hole 921 and forms the discharging tube.

Fig. 32 to 35 illustrate another modified embodiment of the slurry discharging valve device 90 with simplified structural design based on the above-mentioned magnetic adsorption connection scheme of the first support 97 and the second support 98, and improved in sealing structure, in this embodiment, the sealing sleeve 95 includes a first tube 951, a second tube 952 and a third tube 953, the first tube 951 is located in the discharging channel and contains the valve body segment 942, the second tube 952 extends from the slurry discharging hole 931 and forms a material discharging tube, and the third tube 953 can be in sealing abutment with the periphery of the material discharging hole 311.

That is, the above-mentioned modified structure scheme of the slurry discharging valve device 90 with simplified structural design is improved on the sealing structure, the sealing sleeve 95 is integrated with the material discharging pipe and/or the sealing ring, wherein the valve core 94 penetrates the first pipe body 951, so that the whole structure of the valve body 91 is simplified, and the parts are fewer in the disassembling and assembling process, so that the use is more convenient.

Referring to fig. 2, in one embodiment of the food preparation method of the present invention, the food preparation method comprises the steps of:

step S10, cooling and fresh-keeping steps: starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so that the temperature of the food materials in the accommodating cavity is lower than the target temperature;

Step S20, pulping: crushing the food materials in the accommodating cavity, and mixing the crushed food materials with water in the accommodating cavity, wherein the pulping step is performed after the cooling and fresh-keeping step.

Based on the food processor, in this embodiment, the food processor further includes a refrigerating device, where the refrigerating device is configured to cool the food to be processed in the accommodating cavity, so as to achieve the effect of reducing the temperature of the food in the accommodating cavity.

In one embodiment, the food processor further comprises a cup, and the receiving cavity is formed in the cup. The cup body is made of heat preservation materials. And/or, a heat preservation layer is arranged on the inner side and/or the outer side of the cup wall of the cup body, so that the cup body can realize the heat preservation effect on the containing cavity. Thereby making it possible to maintain the temperature inside the cavity and reduce the energy consumption of the refrigerating device.

In this embodiment, the food processor may perform the cooling and refreshing action after the cooling and refreshing function is started. The cooling and fresh-keeping step comprises the steps of starting a refrigerating device, and commanding the accommodating cavity through the refrigerating device so that the temperature in the accommodating cavity is lower than the target temperature. Furthermore, after the cooling and fresh-keeping step, a pulping step may be performed, that is, the food material in the accommodating cavity is crushed, and the crushed food material is mixed with the water injected by the water supply device.

Specifically, in order to better maintain the freshness of the food materials when the cooling and fresh-keeping step is performed, the temperature of the food materials may be controlled to be less than or equal to 30 ℃. In some embodiments, the food material is kept at a temperature ranging from 0 ℃ to 15 ℃ so that the food material is better in preservation effect.

Specifically, the cooling and fresh-keeping functions can be triggered by one or more preset modes. Namely, when the food processor detects that the current moment meets the preset condition, the cooling and fresh-keeping functions can be triggered, wherein the preset condition comprises at least one of the following:

detecting that food to be processed exists in the accommodating cavity;

detecting that the food material to be processed in the accommodating cavity is infiltrated;

the food processor begins to perform a soaking step;

the food processor starts to execute or has completed the food material washing step;

the food processor receives reservation setting;

the temperature in the accommodating cavity and/or the ambient temperature in the space where the food processor is located are/is greater than or equal to a preset temperature.

It will be appreciated that the preset conditions may be provided by the food processor or user-defined settings such that the food processor may perform different functions. The following description will be made one by one with reference to specific use conditions in examples.

Example 1, a temperature-reducing fresh-keeping function control button is arranged on a food processor. The user can start to obtain and close the cooling and fresh-keeping function through the cooling and fresh-keeping control button means. Of course, as an alternative implementation scheme, the food processor may also be provided with a network interface, so that the food processor may be connected with the mobile terminal, so that a user may send a control instruction for starting the cooling and fresh-keeping function to the food processor through the mobile terminal, so as to realize remote starting or closing of the cooling and fresh-keeping function. In example 1, the cool-down fresh-keeping step is performed when a control instruction to start the cool-down fresh-keeping function is received.

Based on example 1, in an application scenario, a user may make fresh soymilk by a food processor while getting up in the morning in order to drink the fresh soymilk in the morning. However, since the people get up in the morning are in a hurry, the dried beans can be washed and then put into the cavity of the food processor in the previous night and soaked in water. So that the food processor can be directly started to prepare soybean milk without the actions of washing and soaking the soybean during the bed rising in the morning. However, when the temperature at night is high, the freshness of the beans is lowered by soaking for a long period of time. Therefore, the user can manually start the cooling and fresh-keeping step after adding beans into the accommodating cavity. And then when the soybean milk is prepared, manually closing the cooling and fresh-keeping step. And controlling the food processor to enter the pulping step.

Example 2, a food processor may detect the presence of processed food material within a receiving cavity. For example, when the user starts the reserved processing function, it is determined that the food material to be processed exists in the accommodation chamber. Or, a food material detection sensor is arranged in the accommodating cavity, so that whether food materials to be processed exist in the accommodating cavity or not can be determined through a detection result. When the existence of food materials in the accommodating cavity is detected, the cooling and fresh-keeping functions are started.

In example 2, the cooling and fresh-keeping function may also be automatically turned off after the pulping step is detected or the food material curing step is detected.

Based on example 2, in an application scenario, when the user starts a function of reserving making of soymilk, it is determined that the user has added food material into the accommodation chamber. Therefore, the cooling and refreshing step can be directly performed. Or when the food materials to be processed in the accommodating cavity are detected, the cooling and fresh-keeping steps are directly executed. And stopping the cooling and fresh-keeping step after the pulping step or the food material curing step is carried out. Therefore, a user does not need to manually control the temperature reduction and preservation steps, and convenience of the food processor is improved.

Example 3 when the food processor determines that the food to be processed has been added to the current holding chamber, it is also possible to detect whether the food to be processed has been infiltrated by a liquid detection sensor provided in the holding chamber. When the food to be processed is soaked, if the upper part enters the pulping step or the food curing step at the moment, the cooling and fresh-keeping step can be executed.

Example 4 the food processor machine was equipped with an automatic soaking function. So that the user can directly add the unfoamed food material directly into the receiving chamber. Alternatively, the food processor is provided with an automatic feeding function. And when the condition of charging is detected to be met, automatically adding dry materials into the containing cavity. The food processor may perform the soaking step after the user or the food processor adds dry ingredients to the receiving cavity. The soaking step comprises the steps of injecting target amount of water into the accommodating cavity and keeping the water for a certain time so as to soak the food materials in the accommodating cavity. For example, in order to increase the delicious degree of soybean milk, it is generally necessary to foam the soybean before making the soybean milk. Based on the food processor in this example, the user may instead add the dried beans directly to the food processor, or the food processor may be provided with a bean storage compartment in which the dried beans may be stored. The food processor may automatically add the dried beans in the bean storage compartment to the holding cavity. Then, after heating the dried beans in the holding chamber, a soaking step may be performed to soak the beans. In this scenario, a longer duration is typically required due to the foaming process. Therefore, the temperature-lowering fresh-keeping step can be performed when the food processor starts to perform the soaking step. To maintain its freshness. Of course, in some embodiments, after the soaking step is performed, if the food processor has not entered the pulping step, the cooling and fresh-keeping step may be performed first, and the cooling and fresh-keeping step may be stopped when the pulping step is started.

Example 5 the food processor is provided with a food material washing function. And executing the food material cleaning step when the food processor starts the food material cleaning function. Wherein, the food material cleaning step includes: detecting the water level in the accommodating cavity;

when the water level is lower than a preset water level, water is injected into the accommodating cavity, so that the water level is higher than or equal to the preset water level;

stirring the accommodating cavity when the water level is higher than or equal to the preset water level;

and after stirring for preset times or preset time, discharging water in the accommodating cavity, wherein the food material cleaning step is executed before the cooling and fresh-keeping step, or is executed simultaneously with the cooling and fresh-keeping step, or is executed between the cooling and fresh-keeping step and the pulping step.

Specifically, after the food processor starts the food material cleaning function, the water level in the accommodating cavity can be detected first, so as to judge whether the water level is lower than the cleaning water level. It is understood that the washing water level is a preset minimum amount of water corresponding to the washing step. Thus, it is also possible to determine in other ways whether the amount of water in the containing chamber is lower than the minimum amount of water corresponding to performing the washing step. And is not limited to being determined only by the water level. Further, when the water level is lower than the cleaning water level, water is injected into the accommodating cavity, so that the water level is higher than or equal to the cleaning water level. And stirring the accommodating cavity when the water level is higher than or equal to the cleaning water level. Alternatively, the whipping blade may be controlled to rotate at a low speed to clean the food material without compromising the integrity of the food material. And discharging the water in the accommodating cavity after stirring for preset times or preset time. Wherein, stirring number of times can be determined according to the rotation angle of the stirring knife.

In example 5, the food material washing step is performed before the temperature-reducing and fresh-keeping step, or simultaneously with the temperature-reducing and fresh-keeping step, or between the temperature-reducing and fresh-keeping step and the pulping step. In an application scenario, a user may add dry beans directly into the holding cavity and then reserve making soymilk. Further, the food processor may determine a timing to initiate the bean washing step based on the reservation information. When the bean washing step is started, the cooling and refreshing step can be simultaneously performed. Or after the bean washing step is finished, the cooling and fresh-keeping step can be further carried out. In another application scenario, after the user starts the function of making soybean milk in a reserved manner, the soybean adding action can be automatically triggered according to the reserved information so as to add dry soybeans into the accommodating cavity. After the bean adding is completed, the food material cleaning step can be performed, and the cooling and fresh-keeping step is performed when the food material cleaning step is started or ended. And after the food material cleaning step is finished, executing a soaking step, and stopping executing the cooling and fresh-keeping step when the soaking step is finished, so as to execute the pulping step. Optionally, in the application scenario, a food material cleaning step may be performed again between the soaking step and the pulping step, so as to improve the freshness of the soybean milk.

It should be noted that, in some application scenarios, the cooling and fresh-keeping steps may be performed first, and then the soaking step may be performed. So that the temperature of the food materials can be reduced through the cooling and fresh-keeping steps, and then the soaking temperature is reduced when water is injected for soaking. Thereby achieving the purpose of guaranteeing the freshness of the food materials.

Example 6 the food processor is provided with a temperature detection sensor such that the temperature in the receiving cavity and/or the ambient temperature in the space in which the food processor is located can be detected by temperature. Further, when the food processor is in a starting state or detects that food to be processed is in the accommodating cavity, if the temperature in the accommodating cavity and/or the ambient temperature in the space where the food processor is located is greater than or equal to a preset temperature, it is judged that the food to be processed in the accommodating cavity may be subject to deterioration, so that the cooling and fresh-keeping steps can be performed. Optionally, in order to avoid frequent triggering of the cooling and preserving step, the cooling and preserving step may be further performed when the temperature in the accommodating cavity and/or the ambient temperature in the space where the food processor is located is greater than or equal to a preset temperature, and the duration of the outdoor space to be processed in the accommodating cavity is further obtained, and the cooling and preserving step is performed when the duration is greater than the preset duration. And stopping executing the cooling and fresh-keeping step after the pulping step is started.

Optionally, based on the solutions corresponding to the foregoing respective examples, as an optional implementation manner, in a process of starting the refrigeration device and refrigerating the accommodating cavity by the refrigeration device so that the temperature in the accommodating cavity is lower than the target temperature, the method specifically includes:

detecting a temperature within the containment chamber;

and when the temperature in the accommodating cavity is higher than a first temperature, starting the refrigerating device, and when the temperature in the accommodating cavity is lower than or equal to a second temperature, closing the refrigerating device, wherein the second temperature is lower than or equal to the first temperature.

The first temperature is less than or equal to the target temperature, and the second temperature is less than or equal to the first temperature. The target temperature may be set by user definition or may be set to a fixed value. Or there may be a food processor that is determined based on ambient temperature. Wherein the higher the ambient temperature, the lower the target temperature. It will be appreciated that this is because the higher the ambient temperature, the more susceptible the food material will deteriorate and therefore the freshness can be maintained at a lower temperature.

Optionally, based on the solutions corresponding to the foregoing respective examples, as another optional implementation manner, in a process of starting the refrigeration device and refrigerating the accommodating cavity by the refrigeration device so that the temperature in the accommodating cavity is lower than the target temperature, the method specifically includes:

Detecting the temperature in the accommodating cavity, and determining the operation power of the refrigerating device according to the temperature in the accommodating cavity, wherein the higher the temperature in the accommodating cavity is, the higher the operation power is, so that the refrigerating device is controlled to perform refrigeration according to the operation power.

For example, a minimum temperature x may be set such that the minimum temperature x bets on an operating power of 0, and further, the operating power is increased bW without increasing the temperature by a ℃. Wherein x, a and b are fixed constants which can be set in a self-defined manner according to actual requirements. The present embodiment is not limited to specific values thereof. For example, x may be set to 5 ℃, a to 1 ℃, and b to 100W.

Optionally, the pulping step includes a crushing step and a water adding step; wherein the method comprises the steps of

The pulverizing step is prior to the water adding step; or alternatively

The pulverizing step is subsequent to the water adding step; or alternatively

The crushing step and the water adding step are performed simultaneously; or alternatively

The water adding step comprises a first water adding step and a second water adding step, and the crushing step is performed on the

Between the first water adding step and the second water adding step, or between the pulverizing step and the first water adding step

The water step is performed simultaneously, or the pulverizing step and the second water adding step are performed simultaneously.

Optionally, the pulping step further comprises a cooking step, wherein the cooking step comprises heating the food material in the accommodating cavity by a heating device so as to cure the food material. Wherein the pulverizing step, the water adding step and the boiling step are sequentially performed; or alternatively

The water adding step, the crushing step and the boiling step are sequentially performed; or alternatively

The crushing step, the water adding step and the boiling step are performed simultaneously; or alternatively

The water adding step, the boiling step and the crushing step are sequentially performed; or alternatively

The boiling step is between the first water adding step and the crushing step; or alternatively

The boiling step and the first water adding step are carried out simultaneously; or alternatively

The boiling step is between the crushing step and the second water adding step; or alternatively

The boiling step is after the second water adding step; or alternatively

The boiling step and the second water adding step are performed simultaneously.

In the technical scheme disclosed in the embodiment, the temperature reduction and fresh-keeping steps are carried out firstly: starting the refrigerating device, refrigerating the accommodating cavity through the refrigerating device so that the temperature of food materials in the accommodating cavity is lower than the target temperature, and then performing pulping: crushing the food material in the accommodating cavity, and mixing the crushed food material with water in the accommodating cavity. The freshness of the food materials to be processed can be maintained through the cooling and fresh-keeping steps, so that the effect of improving the freshness of the soybean milk manufactured by the soybean milk machine is achieved.

Referring to fig. 3, based on the above embodiment, in another embodiment, after the step S20, the method further includes:

step S30, a slurry discharging step: and controlling the pulp discharging valve device to perform pulp discharging operation.

In this embodiment, the food processor further includes a pulp discharge valve and a cup, the accommodating cavity is formed in the cup, the cup further includes a discharge hole communicating with the accommodating cavity, and the pulp discharge valve device is mounted in the cup and connected to the discharge hole; so that the food processor can control the pulp discharging valve device to perform pulp discharging operation.

In addition, an embodiment of the present invention also proposes a food processor including: the food processor further comprises a memory, a processor and a control program of the food processor, wherein the control program of the food processor is stored in the memory and can run on the processor, and the control program of the food processor is executed by the processor to realize the steps of the food preparation method according to the various embodiments.

Furthermore, the embodiments of the present invention also provide a computer-readable storage medium, on which a control program of a food processor is stored, which when executed by a processor, implements the steps of the food preparation method according to the above embodiments.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on this understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) as described above, comprising instructions for causing a food processor (which may be a smart phone or the like) to perform the method according to the embodiments of the present invention.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (9)

1. A method of making food for use in a food processor, the food processor comprising: the accommodating cavity is used for cooling the refrigerating device for cooling the food material to be processed in the accommodating cavity, and the food manufacturing method comprises the following steps:

cooling and preserving: starting the refrigerating device, cooling the food materials to be processed in the accommodating cavity through the refrigerating device so as to enable the temperature of the food materials in the accommodating cavity to be lower than a target temperature, wherein the temperature in the accommodating cavity is detected, and when the temperature in the accommodating cavity is higher than a first temperature, starting the refrigerating device; when the temperature in the accommodating cavity is less than or equal to a second temperature and/or the operation time of the refrigerating device reaches a preset time, the refrigerating device is closed, the second temperature is less than or equal to the first temperature, and the target temperature is less than or equal to 30 ℃; and the cooling and fresh-keeping steps comprise: starting the refrigerating device, and cooling the food materials to be processed in the accommodating cavity through the refrigerating device so as to enable the temperature of the food materials in the accommodating cavity to be 0-15 ℃;

Pulping: crushing food materials in the accommodating cavity, and mixing the crushed food materials with water in the accommodating cavity, wherein the pulping step is performed after the cooling and fresh-keeping step;

the food material cleaning step comprises the following steps: injecting water into the accommodating cavity to enable the water level to be higher than or equal to the cleaning water level; stirring the accommodating cavity; after stirring for preset times or preset time, discharging water in the accommodating cavity, wherein the food material cleaning step is executed before the cooling and fresh-keeping step, or is executed simultaneously with the cooling and fresh-keeping step, or is executed between the cooling and fresh-keeping step and the pulping step;

when a preset condition is met, the cooling and fresh-keeping step is executed, wherein the preset condition comprises at least one of the following:

receiving a control instruction for starting a cooling and fresh-keeping function;

detecting that food to be processed exists in the accommodating cavity;

detecting that the food material to be processed in the accommodating cavity is infiltrated;

the food processor begins to perform a soaking step;

the food processor starts to execute or has completed the food material washing step;

the food processor receives reservation setting;

the temperature in the accommodating cavity and/or the ambient temperature in the space where the food processor is located are/is greater than or equal to a preset temperature.

2. The food preparation method of claim 1, further comprising:

soaking: injecting target amount of water into the accommodating cavity to soak the food in the accommodating cavity, wherein the cooling and fresh-keeping step is executed simultaneously with the soaking step, or the soaking step is executed before the cooling and fresh-keeping step, or the soaking step is executed after the cooling and fresh-keeping step.

3. The food preparation method of claim 2, further comprising:

and a draining step of draining water in the accommodating chamber, wherein the draining step is performed before the pulping step and after the soaking step.

4. The method of claim 1, wherein the cooling and preserving step comprises:

detecting a temperature within the containment chamber;

determining the operation power of the refrigerating device according to the temperature in the accommodating cavity, wherein the higher the temperature in the accommodating cavity is, the higher the operation power is;

and controlling the refrigerating device to refrigerate according to the running power.

5. The method of food preparation according to claim 1, wherein the pulping step comprises:

Crushing, namely beating food materials to be processed through a crushing device; and

a water adding step of injecting water into the accommodating cavity;

wherein:

the pulverizing step is prior to the water adding step; or alternatively

The pulverizing step is subsequent to the water adding step; or alternatively

The crushing step and the water adding step are performed simultaneously; or,

the water adding step comprises a first water adding step and a second water adding step, and the crushing step is performed on the

And the first water adding step and the second water adding step are performed simultaneously, or the crushing step and the first water adding step are performed simultaneously, or the crushing step and the second water adding step are performed simultaneously, wherein the first water adding step and the second water adding step are used for injecting water into the accommodating cavity for a plurality of times.

6. The method of claim 1, wherein the food processor further comprises a pulp discharge valve device and a cup, the receiving chamber is formed in the cup, the cup further comprises a discharge hole in communication with the receiving chamber, and the pulp discharge valve device is mounted to the cup and connected to the discharge hole; the food preparation method further comprises the following steps:

and (3) pulp discharging: and controlling the pulp discharging valve device to perform pulp discharging operation, wherein the pulp discharging step is performed after the pulping step.

7. The food preparation method of claim 1, further comprising a reservation step comprising:

receiving reservation setting information;

determining the execution time points of the cooling and fresh-keeping step and the pulping step according to the reservation setting information, and executing the cooling and fresh-keeping step and the pulping step when the current time point reaches the execution time point.

8. A food processor, the food processor comprising: the food processor further comprises a memory, a processor and a control program of the food processor stored on the memory and capable of running on the processor, wherein the control program of the food processor is executed by the processor to realize the steps of the food preparation method according to any one of claims 1 to 7.

9. A computer readable storage medium, characterized in that the computer readable storage medium has stored thereon a control program of a food processor, which when executed by a processor, implements the steps of the food preparation method according to any one of claims 1 to 7.