CN114587140B - Beverage preparation method and food processor - Google Patents

Abstract

The invention discloses a beverage preparation method and a food processor, which utilize a food processor with a rotatable container to prepare a beverage, wherein the beverage preparation method comprises the steps of rotating the container loaded with slurry at a high speed to generate centrifugal force, enabling at least part of slag in the slurry to be adhered to the inner wall of the container under the action of the centrifugal force, enabling the slurry to flow back to the bottom of the container, thereby realizing the separation of the slag and the slurry, directly pouring the slurry from the container, separating the slag from the slurry by utilizing the centrifugal process without manual operation, being applicable to preparing beverages such as juice, soybean milk and the like, and being better in drinking taste.

Description

Beverage preparation method and food processor

Technical Field

The invention relates to the technical field of electrical appliance structures, in particular to a beverage preparation method and a food processor suitable for the method.

Background

When the household food processor is used for preparing beverages such as soybean milk, the foodstuff is crushed to prepare the soybean milk, the filter screen is needed to be used for filtering the soybean milk after the soybean milk is prepared, the operation is troublesome, the filtering is insufficient, and the soybean milk yield is low. In the related art, the cell-level breaking machine principle is adopted to break the foodstuff, and the slurry prepared by the process does not need to pass slag, but has coarse taste and poor use experience.

Disclosure of Invention

The present invention aims to solve at least one of the technical problems existing in the prior art. Therefore, the invention provides a beverage preparation method, which separates the residue from the slurry through a centrifugal process, does not need manual filtration, and can effectively improve the drinking taste.

The invention also provides a food processor suitable for the beverage preparation method.

A beverage preparation method according to an embodiment of the first aspect of the present invention is applied to a food processor having a rotatable container, the method comprising:

The vessel loaded with slurry is rotated and centrifuged to adhere at least part of the slag in the slurry to the inner wall of the vessel to separate the slag.

The beverage preparation method provided by the embodiment of the invention has at least the following beneficial effects:

the cooking machine with the rotatable container is used for making drinks, the container loaded with the slurry is rotated at a high speed to generate centrifugal force, at least part of the slag in the slurry can be adhered to the inner wall of the container under the action of the centrifugal force, the purpose of separating the slag from the slurry is achieved, the slurry in the slurry can flow back to the bottom of the container, so that the slag and the slurry can be separated, the slurry can be directly poured out of the container, compared with the existing pulping process, the centrifugal process is used for separating the slag from the slurry, manual operation is not needed for filtering, the separation effect is good and high-efficiency, the method is suitable for making drinks such as juice and soybean milk, and the drinking taste is better.

According to some embodiments of the invention, further comprising:

crushing the foodstuff in the container to obtain the slurry.

According to some embodiments of the invention, further comprising:

the foodstuff is heated.

According to some embodiments of the invention, the heating the foodstuff comprises:

heating the foodstuff to a boiling state with a first heating power, and then boiling the foodstuff with a second heating power;

Wherein the first heating power is greater than or equal to the second heating power.

According to some embodiments of the invention, the step of crushing the foodstuff within the container is performed after the heating of the foodstuff to a boiling state at a first heating power.

According to some embodiments of the invention, the first heating power is 800W to 2500W and the second heating power is 5W to 800W.

According to some embodiments of the invention, the foodstuff comprises soy and water, the method comprising:

Crushing the soybeans in the container to obtain soybean milk;

And when the container is rotated for centrifugation, at least part of bean dregs are adhered to the inner wall of the container.

According to some embodiments of the invention, the foodstuff comprises soy and water in a weight ratio of 1:2 to 1:15.

According to some embodiments of the invention, further comprising:

the slurry is heated prior to centrifuging the rotating slurry-laden vessel.

According to some embodiments of the invention, the heating the slurry comprises:

the slurry is stirred during heating, and the stirring speed is 50-200 rpm.

According to some embodiments of the invention, the rotation of the vessel loaded with slurry is at a rotational speed of 500rpm to 5000 rpm for a centrifugation time of 0.5 minutes to 10 minutes.

According to some embodiments of the invention, the crushing of foodstuff within the container comprises:

the foodstuff is crushed by means of a knife set with a rotation speed of 100 rpm to 3000 rpm for a crushing time of 0.2 min to 3 min.

According to an embodiment of the second aspect of the present invention, a food processor includes:

a vessel for holding a slurry;

a driving device for driving the container to rotate;

And the controller is used for controlling the driving device to drive the container to rotate, so that at least part of slag in the slurry is adhered to the inner wall of the container, and the slag is separated.

The food processor provided by the embodiment of the invention has at least the following beneficial effects:

The cooking machine utilizes the work of controller control drive arrangement, rotate through drive arrangement drive container and carry out the centrifugation, make the material sediment in the ground paste can adhere on the inner wall of container under centrifugal force effect, reach the purpose that separates the material sediment from the ground paste, the thick liquid in the ground paste can flow back to the bottom of container, thereby realize material sediment and thick liquid separation, compare with current cooking machine, adopt centrifugal mode with material sediment and thick liquid separation, need not manual operation and filter, the separation effect is good and more efficient, applicable beverage such as preparation fruit juice, soybean milk, the material sediment realizes mechanization with the thick liquid separation, drink taste is better.

According to some embodiments of the invention, the container comprises a cup, wherein at least part of the inner cavity of the cup is gradually narrowed towards the cup opening along the height direction, the inner wall of the cup has an inclination angle alpha, and the alpha is 90 degrees and more than or equal to 60 degrees.

According to some embodiments of the invention, a knife set is arranged in the container, and the controller controls the driving device to drive the knife set to rotate so as to crush foodstuff in the container to obtain the slurry;

the food processor further comprises a heater, and the controller controls the heater to heat the foodstuff;

The controller also controls the heater to boil the foodstuff with a second heating power after heating the foodstuff to a boiling state with a first heating power, wherein the first heating power is greater than or equal to the second heating power.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The invention is further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a flow chart showing the steps of a beverage preparation method according to an embodiment of the present invention;

FIG. 2 is a flow chart of steps of a beverage preparation method according to another embodiment of the present invention;

FIG. 3 is a flow chart of steps of a beverage preparation method according to another embodiment of the present invention;

FIG. 4 is a flow chart showing the steps of a method for preparing soymilk according to an embodiment of the invention;

FIG. 5 is a flowchart showing the steps for heating foodstuff according to an embodiment of the present invention;

FIG. 6 is a flowchart illustrating a process for heating soybeans according to an embodiment of the present invention;

FIG. 7 is a flowchart illustrating steps for crushing soybeans according to another embodiment of the present invention;

FIG. 8 is a flow chart of steps of a beverage preparation method according to another embodiment of the present invention;

FIG. 9 is a flow chart of the steps for stirring slurry according to one embodiment of the invention;

FIG. 10 is a flowchart showing a method for preparing soybean milk according to an embodiment of the present invention;

FIG. 11 is a schematic view of a cup assembly according to an embodiment of the invention;

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

FIG. 13 is a cross-sectional view of the knife pack and chassis assembly of FIG. 12;

FIG. 14 is a schematic view of the abrasive article of FIG. 12;

FIG. 15 is a bottom view of FIG. 14;

FIG. 16 is a cross-sectional view of FIG. 14;

FIG. 17 is a schematic view of the structure of the chassis and heat-generating plate of FIG. 12;

FIG. 18 is a schematic view of a cup assembly according to another embodiment of the invention;

FIG. 19 is a cross-sectional view of FIG. 18;

FIG. 20 is an enlarged view of FIG. 12 at A;

Fig. 21 is an enlarged view at B in fig. 19;

fig. 22 is a schematic structural diagram of a food processor according to an embodiment of the invention;

FIG. 23 is a schematic view of the latch assembly of FIG. 22;

FIG. 24 is an exploded view of FIG. 23;

fig. 25 is a cross-sectional view of a food processor according to another embodiment of the present invention;

fig. 26 is a cross-sectional view of a food processor according to another embodiment of the present invention;

Fig. 27 is a cross-sectional view of a food processor according to another embodiment of the present invention;

Fig. 28 is an enlarged view of fig. 27 at C;

FIG. 29 is a schematic view of the first connecting mechanism of FIG. 28;

FIG. 30 is an exploded view of FIG. 29;

FIG. 31 is a cross-sectional view of FIG. 29;

fig. 32 is an enlarged view of D in fig. 31.

Reference numerals:

A cup assembly 100;

A cup 110; a cavity 111; an upper cup 112; a cup mouth 1121; a spoiler 1122; a guide bevel 1123; a chassis 113; first abrasive teeth 1131; a first mounting groove 114; rotating the column 115; a deflector ring 116;

A rotation shaft 120;

a knife bank 130; a grinding member 131; second abrasive tooth 1311; a connector 1312; a polishing body 1313; spoke portion 1314; a tray body 1315; a guide 1316; a top knife 132; an upper cutter 133;

a grinding channel 140;

A housing 150; a second mounting groove 151; a housing 152; a cover 153; a clamping groove 154;

A cup cover 160; a cover 161; an air outlet hole 1611; a seal ring 162; a first sealing structure 1621; a second sealing structure 1622; a deflector surface 1623;

a heat-generating plate 170;

a body 200; a motor 210; a tray 220; a flange 221; a shock pad 230; a weight 240;

A latch assembly 300; a shackle 310; a support cover 320; a through hole 321; positioning posts 322; a water guide groove 323; a fixing post 324; a cushion pad 325; a bottom cover 330; a locking ring 340; a second rack 341; a drive mechanism 350; a catch piece 351; a first rack 3511; a latch handle 352;

A circuit connection assembly 400; a first electrode 410; screw posts 411; a second electrode 420; an electrode groove 430; an electrode cover 440; screw via 441;

Food processor 1000.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, the description of first, second, etc. is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present invention, it should be understood that references to orientation descriptions, such as directions of up, down, left, right, etc., are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description and simplification of the description, and do not indicate or imply that the apparatus or element in question must have a specific orientation, be constructed and operated in a specific orientation, and therefore should not be construed as limiting the invention.

In the description of the present invention, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present invention can be determined reasonably by a person skilled in the art in combination with the specific content of the technical solution.

The beverage preparation method according to the embodiment of the present invention is described with reference to fig. 1 to 10, and is suitable for preparing beverages such as juice, soybean milk, and the like.

Referring to fig. 1, the beverage preparation method according to the embodiment of the present invention includes, but is not limited to, the following steps:

and step S100, rotating the container loaded with the slurry for centrifugation, so that at least part of slag in the slurry is adhered to the inner wall of the container to separate the slag.

It will be appreciated that the beverage preparation method of the embodiment is applied to a food processor 1000, and the food processor 1000 has a rotatable container, and the slurry to be filtered is centrifuged, so that the material and the residue can be separated rapidly. Specifically, the container filled with the slurry is driven to rotate at a high speed for centrifugation, at least part of the slag in the slurry can be adhered to the inner wall of the container under the action of the centrifugal force, and the slurry in the slurry can flow back to the bottom of the container, so that the slag is separated, and the slag is separated from the slurry.

The slurry may be a mixture of the residue obtained by crushing, grinding, or the like, and the slurry, and the residue may be particulate such as food residue, or the like, and the residue may be separated from the slurry for a good drinking taste. It will be appreciated that the slurry thus produced may be poured into a vessel for centrifugation, or the foodstuff may be treated in the vessel to provide a slurry, which is not further limited herein. In the centrifugation process, when the rotating speed of the container is large enough, centrifugal force is generated on the slurry, so that at least part of the slag can be adhered to the inner wall of the container, the slag is separated from the slurry, and the slag adhered to the inner wall is separated from the slurry after the centrifugation is finished. It is easy to understand that the larger the rotation speed of the container is, the more slag is adhered to the inner wall of the container, the better the slag separating effect is, and the better the drinking taste of the slurry is.

It is understood that the residue of foodstuff, which is mostly insoluble dietary fibers, is mixed in the slurry, has a certain viscosity and can be tightly attached to the inner wall of the container in a centrifugal state. For example, the foodstuff may be fruit, the fruit is crushed and centrifuged, the pomace adheres to the inner wall of the container, so that the pomace and the juice are rapidly separated, the juice can be poured from the container for direct drinking, the pomace remains in the container, and the purer juice can be obtained without manual filtration. For another example, the slurry can be soybean milk, and after centrifugal treatment, the bean dregs are adhered to the inner wall of the container, and the bean dregs are separated from the slurry, so that the soybean milk with the bean dregs filtered is obtained, manual filtration is not needed, and the soybean milk has better drinking taste.

Referring to fig. 2, the beverage preparation method according to the embodiment of the present invention includes, but is not limited to, the following steps:

And step S110, crushing the foodstuff in the container to obtain slurry.

And step S120, rotating the container for centrifugation, wherein at least part of the slag adheres to the inner wall of the container so as to separate the slag.

It will be appreciated that the foodstuff is crushed to give a slurry prior to centrifugation. Specifically, firstly, foodstuff is put into a container, the foodstuff is crushed by using a food processor 1000, slurry is obtained after the foodstuff is crushed, then the food processor 1000 drives the container to rotate at a high speed for centrifugation, the material slag in the slurry can be adhered to the inner wall of the container under the action of centrifugal force, and the slurry in the slurry can flow back to the bottom of the container, so that the material slag is separated, and the separation of the material slag and the slurry is realized.

The food processor 1000 is understood to be an electric appliance capable of producing various foods such as fruit juice, soybean milk, jam, and meat stuffing, and the food processor 1000 is capable of crushing the foods in the container to crush the foods into slurry. Compared with a traditional food processor, the container can rotate and has a centrifugal treatment function, for example, the container is driven by a motor to rotate, and under the high-speed rotation state, centrifugal force is generated in the container, so that the slag is far away from the center of the container and is clung to the inner wall of the container under the action of the centrifugal force, the slag can be adhered to the inner wall of the container, and the slurry can flow back to the bottom of the container, so that the slag is separated from the slurry, and therefore, the slurry can be directly poured out of the container, and the slag can be adhered to the inner wall of the container, so that the slag and the slurry are separated.

In an embodiment, in the step of crushing the foodstuff in the container, the foodstuff in the container is crushed by the knife set 130 of the food processor 1000, and the knife set 130 rotating at a high speed can cut the foodstuff into slag. It will be readily appreciated that when the knife set 130 is in operation, the container is stationary and not rotated, so that the knife set 130 is fully in contact with foodstuff for crushing, and after crushing, the container is rotated for centrifugation, and the knife set 130 is not rotated during centrifugation, or the knife set 130 is removed from the container and then centrifuged. In addition, the crushing step is not limited to the crushing by the knife set 130, and may also employ the process technologies such as grinding crushing, extrusion crushing, etc., which will not be described herein.

It will be appreciated that the foodstuff is not limited to one type and may be pulped with a different foodstuff mix, for example, soy with millet mix. According to the crushing difficulty of different materials, a user can properly prolong the crushing time, or put different foodstuff into the container in batches, so that the crushing effect is improved, and the centrifugal separation effect is better.

Taking soymilk preparation as an example, soymilk preparation methods include, but are not limited to, the following steps:

Step S111, adding soybeans and water into a container, and crushing the soybeans to obtain soybean milk;

In step S121, the rotating container is centrifuged, and at least part of the okara adheres to the inner wall of the container to separate the okara.

It can be understood that soybeans in a container are directly crushed to obtain raw soybean milk, and compared with the traditional soybean milk manufacturing process, the embodiment of the invention adopts a centrifugal technology to separate the soybean milk from the soybean dregs, thereby realizing automatic separation without manual filtration; after centrifugal treatment, substances which cannot be digested and absorbed, such as insoluble dietary fibers, bean hulls and the like, in the soybean milk are separated, at least part of bean dregs are adhered to the inner wall of the container, the soybean milk is directly poured out of the container and heated, and the soybean milk can be prepared and drunk according to the taste after being heated, so that the bean dregs are effectively removed, the taste of the soybean milk can be improved, and the problems of dyspepsia and the like caused by macromolecular insoluble dietary fibers, such as the bean hulls and the like can be avoided.

It should be noted that, the container that adopts can be cup 110 structure, considers in the centrifugation in-process, and thick liquid in the cup 110 can be along inner wall upward movement, and the embodiment can adopt the cup 110 that the inner chamber is the toper, and the inner chamber of cup 110 is narrowed gradually from bottom to top, can make the material sediment follow the inner wall adhesion in the centrifugation like this, and thick liquid can concentrate in cup 110 bottom, is favorable to the balance at the centrifugation, makes the centrifugation more stable, and the centrifugation separation effect is better.

It can be understood that the slurry in the cup 110 is tightly attached to the inner wall under the action of centrifugal force under the condition that the rotation speed of the cup 110 is large enough, after a certain period of centrifugal treatment, the slag can be attached to the inner wall, and the slurry can flow back to the bottom of the cup 110, so that the slag is separated from the slurry, and the purpose of separating the slag from the slurry is achieved. In the centrifugal treatment process, the rotation speed of the cup body 110 is 500-5000 rpm, different rotation speeds can be selected for centrifugal treatment according to the amount and the type of foodstuff, the centrifugal time is controlled to be between 0.5 and 10 minutes, and the centrifugal time is understood to be long enough, so that a better slurry-slag separation effect can be ensured. For example, after foodstuff is crushed to form slurry, the cup 110 is controlled to rotate at a rotation speed of 3000 rpm, the centrifugation time is 3 minutes, most of the material slag can be adhered to the inner wall of the cup 110 after the centrifugation treatment, automatic separation of the material slag and the slurry is realized, manual operation is not needed, and the slurry-slag separation effect is remarkable.

Referring to fig. 3, in an embodiment, the beverage preparation method includes, but is not limited to, the following steps:

Step S130, heating the foodstuff in the container;

Step S140, crushing foodstuff to obtain slurry;

And S150, rotating the container for centrifugation, wherein at least part of the slag adheres to the inner wall of the container so as to separate the slag.

It will be appreciated that the foodstuff is heated prior to centrifugation of the rotating container, and is suitable for foodstuff that requires heating. The food processor 1000 has a heating function. Specifically, foodstuff in the container is heated, then the foodstuff is crushed, slurry is obtained after the foodstuff is crushed, finally the container is driven to rotate at a high speed for centrifugation, so that the material slag and the slurry are separated, and the separated slurry can be directly drunk without additional heating for boiling. Wherein, heating time and heating temperature can be set for according to different foodstuff, to the degree of difficulty of cooking of different materials, can put in the container with different foodstuff batch, can enough guarantee the nutritive value of foodstuff, can improve slurrying effect again. For example, when soybean milk is prepared, soybean is boiled and boiled for a period of time, and the soybean boiled by heating is more likely to be broken, so that the pulping effect is better.

In addition, considering that the slag adheres to the inner wall of the vessel after the slurry is centrifuged, the bottom of the paste is likely to occur when the heating is performed. Thus, in the method of the example, the foodstuff is heated prior to centrifugation, and the residue is separated from the slurry by centrifugation, and the slurry is poured from the container for direct consumption without manual filtration. It will be appreciated that the foodstuff heating step and the crushing step are not limited to the sequence shown in the examples, but the foodstuff may be crushed and then heated.

Referring to fig. 4, a method for preparing soymilk is illustrated as an example, including but not limited to the following steps:

step S131, adding soybean and water into a container and heating;

step S141, crushing soybeans to obtain slurry;

And step S151, rotating the container for centrifugation, wherein at least part of the bean dregs are adhered to the inner wall of the container so as to separate the bean dregs.

Wherein, the soybean is thoroughly cooked in the heating process to eliminate trypsin blocking factors in the soybean, so as to ensure the edible safety of the soybean milk. Specifically, firstly cleaning soybeans, removing impurities, cleaning dust, stains and the like on the surfaces of the soybeans, putting the cleaned soybeans into a container, adding a certain amount of water, then starting the operation of the food processor 1000, heating the soybeans and the water, boiling and continuously heating for a preset time, and crushing the soybeans to finish pulping; finally, the container is controlled to rotate at a high speed for centrifugal treatment, and bean dregs are adhered to the inner wall of the container under the action of centrifugal force, so that the bean dregs are separated, the separation of the bean dregs and the soybean milk is realized, the soybean milk can be directly poured out of the container for drinking, the soybean milk has good taste, the operation is simple, manual filtration is not needed, the cleaning is more convenient, and the problems of easy scalding, complex operation and the like due to manual filtration are avoided.

It can be appreciated that in the step of heating the foodstuff, different heating powers may be used for the heating treatment, for example, different heating powers are used for different foodstuff, so that the nutritional value of the foodstuff can be ensured, and the pulping effect can be improved; for example, in the heating process, different heating powers are adopted for heating alternately, so that the heating effect is better, the problem of bottom pasting is avoided, the nutritional value of the foodstuff is ensured, and the beverage has better drinking taste.

When the soybean milk is prepared, the soybean and the water are treated according to a certain proportion, other foodstuffs can be added for matching, the soybean milk is obtained after crushing treatment, then the soybean milk is subjected to centrifugal treatment, the rotating speed of the container is controlled to be more than 3000/min, the centrifugal time is controlled to be more than 1 min, and most soybean residues can be adhered to the inner wall of the container, so that the soybean residues and the slurry are effectively separated, and the purer soybean milk is obtained without manual filtration and has better drinking taste.

It will be appreciated that different heating powers may be used to heat the foodstuff in order to increase the heating efficiency. Specifically, during heating, the foodstuff is heated by using first heating power, the foodstuff is heated to a boiling state, and then the foodstuff is heated by using second heating power, so that the foodstuff is continuously heated by the second heating power for boiling, wherein the first heating power is larger than or equal to the second heating power, the first heating power can be understood as high power, and the heating time of the first heating power can be set to be a first preset time; the second heating power can be understood as low power, and the heating time of the second heating power can be set to be a second preset time, that is, the heating process adopts high power to heat the first preset time, and then adopts low power to heat the second preset time. Different first heating power and second heating power and first preset time and second preset time are set for different foods, so that the nutritional value of the foods can be ensured. Of course, the first heating power and the second heating power can be alternatively heated, so that the pulping period can be shortened, the occurrence of bottom pasting is effectively avoided, and the pulping effect is improved.

Referring to fig. 5, in an embodiment, step S130 includes, but is not limited to, the following steps:

in step S132, the soybean and water are heated to boiling state by the first heating power, and then boiled by the second heating power.

Wherein the power value of the first heating power is 800W to 2500W, the heating time of the first heating power is 5 seconds to 60 seconds, the power value of the second heating power is 50W to 800W, and the heating time of the second heating power is 5 minutes to 60 minutes. For example, 30g of soybean is weighed, the soybean and water are added into a container according to the weight ratio of 1:10, the soybean and the water are heated by adopting the heating power of 1500W, the soybean and the water are boiled to be boiling in 1 minute, then the heating power is switched to be 500W for heating the soybean, the heating time is 15 minutes, and the soybean is crushed after boiling, so that the crushing effect is improved, the prepared soybean milk is higher in rate, and the soybean milk has better drinking taste.

It will be appreciated that the foodstuff may be heated by different heating powers, and may be crushed and then heated. Specifically, the foodstuff is heated to a boiling state by adopting a first heating power, then the foodstuff is crushed, then the crushed foodstuff is heated by adopting a second heating power, for example, soybean and water are heated by adopting a heating power of 1500W, the soybean is crushed after the foodstuff is heated to boiling, then the foodstuff is boiled by utilizing a heating power of 500W, and then the foodstuff is centrifuged after the boiling is finished, so that bean dregs and soybean milk are separated, and a soybean milk finished product is prepared. The soybeans boiled by heating are easier to crush, the crushing efficiency is improved, the particles obtained by crushing the soybeans are smaller, and the soybeans are heated after being crushed, so that the soybean milk yield is improved, the extraction rate of soybean protein and soybean isoflavone is higher, and the pulping effect is better.

Referring to fig. 6, in an embodiment, the heating and crushing steps include, but are not limited to, the following steps:

Step S133, heating the soybeans and water to a boiling state with a first heating power;

Step S134, crushing soybeans to obtain slurry;

In step S135, the slurry is boiled with the second heating power.

The foodstuff is crushed to form slurry, and when the slurry is heated by the second heating power, the slurry is stirred, so that occurrence of paste bottom can be avoided. It can be understood that the higher the concentration of the slurry is, the easier the phenomenon of the paste bottom is, so that the low power is adopted for heating in the boiling process, and the paste bottom is effectively prevented by stirring the slurry, so that the soybean milk with higher protein content is also obtained, and the pulping effect is better.

In addition, according to the preparation method of the soybean milk, the heating time of the soybean is controlled to be more than 5 minutes, the aim of eliminating trypsin blocking factors in the soybean is fulfilled, the specific heating time is set according to the weight of the soybean, and the heating time is between 5 minutes and 60 minutes. For example, beans and water are boiled with 1500W heating for 1 minute, then crushed for 3 minutes with a rotation speed of 3000 rpm, and then heated with 500W for 20 minutes, thereby completing pulping; finally, the container is controlled to rotate at a high speed for centrifugal treatment, the bean dregs are separated from the soybean milk, manual filtration is not needed, and the soybean milk preparation is more efficient.

It can be appreciated that in the embodiment, the foodstuff is heated during the crushing process, so that the crushing effect can be further improved, particularly for the soybean milk preparation process, the soybean is crushed while being heated, so that the soybean is crushed more easily, the efficiency is higher, and the pulping effect is further improved.

It should be noted that, the heating power used in the crushing may be high power or low power, for example, referring to fig. 7, step S140 may include the following steps:

step S142, when soybean is crushed, the soybean is crushed at a rotating speed of 3000 rpm for 1 minute;

In step S143, 1500W is used for heating, and crushing is continued after heating for 1 minute, wherein the crushing time is 1 minute.

It is understood that the crushing and heating steps may be performed simultaneously, i.e. while crushing and heating, for example, when crushing soybeans at a rotation speed of 3000 rpm, heating is performed by using heating power of 500W, so that the heating and crushing are performed simultaneously, which is beneficial to improving the crushing effect and avoiding the occurrence of a bottom pasting phenomenon during heating.

Referring to fig. 8, in some embodiments, the beverage preparation method includes, but is not limited to, the following steps:

step S160, heating the slurry in the container;

in step S170, the rotating container is centrifuged, and at least part of the slag adheres to the inner wall of the container to separate the slag.

It can be understood that the slurry to be filtered can be heated first and then centrifuged, so that the rapid separation of the discharged slag can be realized, and the specific process is not repeated. The separated slurry can be directly drunk without additional heating.

Referring to fig. 9, in the embodiment, step S160 further includes the following steps:

In step S161, the slurry is stirred at a rotation speed of 50 to 200 rpm when the slurry is heated.

It is understood that the stirring process may be performed by using a stirrer of the food processor 1000, for example, the motor 210 drives the stirrer to stir; the stirring may be performed manually, by holding the stirrer while heating, or at regular time intervals. In the embodiment, the stirring process can be performed by using the cutter set 130, and when the cutter set 130 breaks, the rotation speed of the cutter set 130 is higher, so that the foodstuff can be quickly cut up; and the stirring effect can be achieved when the cutter set 130 rotates at a low speed, so that the stirring efficiency is higher. The stirring speed of the cutter set 130 can be adjusted according to the slurry concentration, for example, when the slurry concentration is too high, the stirring speed can be adjusted to be increased.

In an embodiment, the rotation speed of the cutter set 130 during crushing is in the range of 100 to 3000 rpm, and the rotation speed of the cutter set 130 during stirring is in the range of 50 to 200 rpm, wherein the crushing time is controlled in the range of 0.2 to 2 minutes. For example, soybean and water are heated with high power, the soybean is crushed with a rotating speed of 3000 rpm after the soybean is heated to boiling, the slurry is boiled with low power after the soybean is crushed for 2 minutes, the slurry is stirred with a rotating speed of 100 rpm during boiling, and centrifugal treatment is carried out after boiling, so that soybean residues and soybean milk are separated to prepare a soybean milk finished product, a higher soybean milk yield is ensured, the extraction rate of soybean protein and soybean isoflavone is improved, and the pulping effect is better.

When making soybean milk, the weight ratio of soybean to water is 1:2 to 1:15, and can be prepared according to the tastes of users. For example, 50g of soybean is selected, the soybean is cleaned, the soybean and water are added into a container according to the weight ratio of 1:10, then the steps of heating, crushing, boiling and centrifuging are carried out, and after the centrifuging treatment, the bean dregs and the soybean milk can be separated, so that a soybean milk finished product is prepared, manual soybean milk filtration is not needed in the preparation process, and the use experience of a user is high.

In order to more clearly illustrate the specific step flow of the beverage preparation method in the above embodiments, a specific example will be described below.

As shown in fig. 10, fig. 10 is a flowchart of a soymilk preparation method provided by an example of the invention, and the flowchart specifically includes:

step S211, weighing 50g of soybeans and cleaning;

Step S212, adding soybean and water into the cup body according to the weight ratio of 1:10;

Step S213, heating with 1500W, boiling soybean and water;

Step S214, crushing soybeans at a rotating speed of 3000 rpm, heating at 1500W for 1 min, heating for 0.5 min, and crushing at a rotating speed of 3000 rpm for 1 min;

step S215, alternately boiling with 500W and 1500W for 0.5 min and boiling for 15 min;

step S216, centrifuging at a rotating speed of 3000 rpm for 1 minute to adhere the bean dregs to the inner wall of the container so as to separate the bean dregs;

And S217, pouring out the soybean milk from the cup body to prepare a soybean milk finished product.

It can be understood that the soybean milk prepared by the soybean milk preparation method according to the embodiment does not need to be subjected to manual filtration, avoids risks such as scalding, and the like, and compared with the traditional soybean milk preparation process, the soybean milk prepared by adding a centrifugal process to separate substances such as insoluble dietary fibers, bean hulls and the like which cannot be digested and absorbed in the soybean milk, not only can improve the inlet feel of the soybean milk, but also can avoid dyspepsia caused by macromolecular insoluble dietary fibers, effectively improves the yield and protein extraction rate of the soybean milk, the yield of the soybean milk can be up to 85%, the protein extraction rate is more than 65%, and the isoflavone content of the soybean is up to 15mg/100ml to 20mg/100ml, namely, the isoflavone content of the soybean is 15mg to 20mg in 100ml of the soybean milk.

A food processor 1000 according to an embodiment of the present invention is described with reference to fig. 11 to 32.

Referring to fig. 11, a cooking machine 1000 according to an embodiment of the present invention includes a machine body 200 and a container, the container is mounted on the machine body 200, the container is used for placing slurry, the container is rotatably mounted on the machine body 200, a driving device and a controller are mounted in the machine body 200, the driving device can drive the container to rotate, the controller can control the driving device to work, wherein the controller can perform corresponding cooking on foodstuff according to the selection of a user, the controller can be understood as a control circuit board in the cooking machine 1000, and the specific structure of the controller is not shown in the drawing.

In the embodiment, when the slurry is required to be processed, the driving device is controlled by the controller to drive the container to rotate, and the slurry is subjected to centrifugal processing, so that at least part of the slurry in the slurry can be adhered to the inner wall of the container, and the slag is separated from the slurry, so that the slag and the slurry slag are separated, the filtering is not required to be performed by manual operation, the efficiency is higher, and the device is applicable to making beverages such as juice and soybean milk.

Referring to fig. 11, a food processor 1000 shown in fig. 11 is illustrated as a specific example, and the food processor 1000 includes a body 200 and a cup assembly 100, the cup assembly 100 being mounted to an upper end of the body 200. The cup assembly 100 includes a cup 110 and a rotating shaft 120, where the cup 110 can be understood as a container in the above embodiment, and a cavity 111 is formed in the cup 110, and the cavity 111 is used for accommodating foodstuff to be processed. The upper end of holding chamber 111 is equipped with the opening, and the user can pack into the foodstuff that needs to arrange through the opening, also can pour out foodstuff or the ground paste after arranging in holding chamber 111, still can wash the inner wall of cup 110 through the opening, and its convenient to use also is convenient for wash.

It is understood that the rotating shaft 120 may be fixedly connected to the cup 110, or may be connected by a clutch device (such as a one-way bearing, or other structures capable of controlling the rotating shaft 120 and the cup 110 to be fixed or separated), and the rotating shaft 120 may drive the cup 110 to rotate along a first direction, which is clockwise or counterclockwise, which is not limited herein. When the cup body 110 rotates, the slurry in the containing cavity 111 contacts with the inner wall of the cup body 110 under the action of centrifugal force, the slag in the slurry after centrifugation is adhered to the inner wall of the cup body 110, and the slurry flows back to the bottom of the containing cavity 111, so that the slag is separated from the slurry, the separation of the slurry from the slag is realized, the slurry and slag separation effect is good, and the taste of the slurry is improved. And the slurry after centrifugal filtration can be poured out from the opening at the upper end of the container 111, so that the slurry can be easily poured out, however, the residue remains in the cup 110, and the cup 110 is convenient to use and clean without manual operation.

It should be noted that, when the controller controls the cup 110 to rotate for centrifugal treatment, the rotation speed of the cup 110 ranges from 500 rpm to 5000 rpm, and the centrifugal time can be controlled between 0.5 min and 10 min according to the amount and the type of the foodstuff, so that the centrifugal time is long enough to ensure a better separation effect. For example, after soybean is crushed to form slurry, the cup 110 is controlled to rotate at a rotating speed of 3000 rpm, the centrifugation time is 2 minutes, and after the centrifugation treatment, bean dregs can be adhered to the inner wall of the cup 110, so that the bean dregs are separated out, manual operation is not needed, and the slurry-dreg separation effect is remarkable.

Referring to fig. 11, in order to enhance the centrifugal processing effect, the cup 110 generally has an upwardly narrowed structure. It is understood that, along the height direction of the cup 110, the cavity 111 has a plurality of cross sections, where the cross sections refer to the space enclosed by the inner wall of the cup 110 and a plurality of planes perpendicular to the height direction of the cup 110 respectively form surfaces. The cross section with the largest cross section is defined as a first cross section, that is, the area of the other cross sections is equal to or smaller than the first cross section, and it is understood that the first cross section may be the connection between the upper cup 112 and the bottom plate 113 in fig. 12, or may be on the upper cup 112 or may be on the bottom plate 113, which is not specifically limited herein. When the area of the partially continuous cross-section is equal to the cross-sectional area of the first cross-section, then the portion of the cup 110 is a cylindrical segment and when the area of the partially continuous cross-section gradually decreases upward from the first cross-section, the portion of the cup 110 is a conical segment. It should be noted that, the cross-sectional area of the cavity 111 of the cup assembly 100 in this embodiment gradually decreases from the first cross-sectional area upwards, so that the overall structure of the cup 110 is a cone, or includes at least one section of cone from bottom to top, so that the component force of the slurry upwards can be reduced, the amount of the slurry moving upwards is reduced, and the slurry is ensured to be more accumulated at the lower part of the cup 110, thereby better separating the slag from the slurry in the slurry, and better separating effect. It is understood that the cross section of the cavity 111 may be circular, elliptical, hexagonal or other shapes, which are not specifically limited herein; when the cross section of the cavity 111 is circular, the processing is more convenient, and the rotation is more stable, which is beneficial to reducing the shake of the cup assembly 100 and improving the stability of the cup assembly 100.

In addition, in the cup assembly 100 of the embodiment, the cross-sectional area of the cavity 111 gradually decreases downwards from the first cross-section, which is beneficial to guiding the slurry at the bottom of the cavity 111 upwards in the centrifugal rotation process, so that most of the slurry can flow on the inner wall of the cup 110, and most of the slurry is guided to the inner wall of the cup 110, so that the slurry is easier to adhere to the inner wall of the cup 110, and the separation effect is improved.

Referring to fig. 12, it will be appreciated that the cup 110 includes an upper cup 112 and a bottom plate 113, the upper cup 112 and the bottom plate 113 being connected to each other and disposed up and down, the upper cup 112 and the bottom plate 113 being fastened by a fastener such as a bolt, thereby sealing the junction of the upper cup 112 and the bottom plate 113; and the cup 110 adopts split type structural design, is convenient for processing, reduction in production cost. Along the height direction of the cup body 110, the cross-sectional area of the inner wall of at least part of the upper cup body 112 gradually decreases along the direction away from the chassis 113, so that at least one section of cone is formed on the upper cup body 112 from bottom to top, thereby being capable of reducing the upward component force of slurry, reducing the amount of slurry moving upwards, ensuring that the slurry is gathered on the chassis 113 more, separating the slag from the slurry, better realizing the separation of the slag and the slurry, and better separating effect. It will be appreciated that the cross-section of the upper cup 112 may be circular, elliptical, hexagonal or other shapes, and is not specifically limited herein.

Referring to fig. 12, it can be understood that the upper cup 112 has a cone structure, so that in the centrifugal separation process of slurry, the upward component force of slurry can be reduced, the amount of slurry moving upwards is reduced, and more slurry is ensured to be gathered on the chassis 113, so that the separation of slag and slurry is realized, and the slurry-slag separation effect is improved. Moreover, the upper cup 112 with the cone structure has smaller processing difficulty and lower processing cost. The upper end of the upper cup 112 is formed with a cup opening 1121, so that the slurry in the cavity 111 can be poured out conveniently, and the cup opening 1121 can be cylindrical, conical or inverted conical, and is not limited herein.

Referring to fig. 12, it can be understood that the inclination angle α of the inner wall of the upper cup 112 is α, which satisfies: 90 DEG alpha is more than or equal to 60 deg. When the inclination angle alpha is larger than 90 degrees, the upper cup body 112 is of a reverse cone structure, slurry in the containing cavity 111 is easy to overflow from the cup opening 1121 under the action of centrifugal force, and after the centrifugal separation of the slurry is finished, the slurry in the slurry is separated downwards in the process of backflow, so that slag adhered to the inner wall of the upper cup body 112 is carried away, and the slurry-slag separation effect is affected; when the inclination angle α is smaller than 60 °, the capacity of the upper cup 112 is smaller, the overall structure of the cup assembly 100 is larger, and the space utilization is lower. Therefore, when the inclination angle α satisfies the above range, the upper cup 112 has a cone structure, so that the upward component force of the slurry can be reduced, the amount of the slurry moving upward can be reduced, the slurry is ensured to be more accumulated on the chassis 113, and the slag is adhered to the inner wall of the upper cup 112, thereby better realizing the separation of the slag and the slurry, and improving the effect of separating the slag.

Referring to fig. 11, it can be understood that, the inner wall of the upper cup 112 is provided with the turbulence ribs 1122, the turbulence ribs 1122 extend along the up-down direction of the upper cup 112, the turbulence ribs 1122 are provided with a plurality of turbulence ribs 1122, and the plurality of turbulence ribs 1122 are uniformly distributed along the circumferential direction of the upper cup 112, so that the flow velocity of slurry can be reduced, thereby enabling slag to be more easily attached to the inner wall of the upper cup 112, and enabling slurry to more easily flow back to the chassis 113, separating the slag, further realizing the separation of the slurry and the slag, and improving the centrifugal separation effect.

Referring to fig. 12, in this embodiment, when the rotating shaft 120 rotates in the second direction, i.e. the direction opposite to the first direction, the rotating shaft 120 drives the knife set 130 to rotate relative to the cup 110, so as to grind, the knife set 130 grinds the foodstuff, thereby breaking the cell wall of the cells in the foodstuff, fully releasing vitamins, minerals, phytochemicals, proteins, moisture, etc. in the cells, so as to obtain foodstuff with smaller particle size, and realize cooking processing of the foodstuff. The cutter set 130 may take various forms, such as a stirring cutter or a grinding cutter, where the stirring cutter may be fixedly mounted on the end of the rotating shaft 120 by a screw, and the grinding cutter is sleeved on the side of the rotating shaft 120 near the end.

In addition, when the rotation shaft 120 rotates along the first direction, the cup body assembly 100 achieves centrifugation, the knife set 130 and the cup body 110 synchronously move, so that the foodstuff in the cup body 110 is ensured not to be disturbed, and the separation of the material slag and the slurry is achieved under the action of the centrifugal force. It should be noted that, the manner in which the cup assembly 100 implements cooking may be that the rotating shaft 120 drives the knife set 130 to grind foodstuff in the cavity 111, and after grinding to form slurry, the rotating shaft 120 drives the cup 110 to rotate, and the slurry is centrifuged, so as to implement slurry-residue separation. In addition, in the grinding process, the slurry is driven by the cutter set 130 to form a vortex, the vortex moves upwards along the inner wall of the conical cup 110, and the vortex flows back to the cutter set 130 under the combined action of gravity and the turbulence ribs 1122 to form a vortex in the vertical direction, so that more contact exists between foodstuff and the cutter set 130, and the grinding efficiency is improved.

It should be noted that, in the embodiment, the driving device is the motor 210, the motor 210 is controlled by the controller to drive the knife set 130 to crush, the rotation speed of the knife set 130 can be set by the controller to control the rotation speed of the motor 210, in the embodiment, the rotation speed range of the knife set 130 during crushing is 100 rpm to 3000 rpm, and different rotation speeds can be adopted for crushing according to different foodstuffs, and it can be understood that the higher the rotation speed of the knife set 130, the better the foodstuff crushing effect.

Referring to fig. 12, it can be understood that a first mounting groove 114 is formed at the lower end of the cup 110, a rotation shaft 120 is disposed in the first mounting groove 114 and the cavity 111 in a penetrating manner, and a one-way bearing is mounted between the rotation shaft 120 and the first mounting groove 114. It should be noted that a one-way bearing is a bearing that can freely rotate in one direction and lock up in the other direction. Therefore, when the rotation shaft 120 rotates in the first direction, the rotation shaft 120 and the cup 110 are interlocked and rotated synchronously, thereby realizing a centrifugal operation; when the rotation shaft 120 rotates in the second direction, the rotation shaft 120 and the cup 110 relatively rotate, and the cup 110 does not rotate along with the cutter set 130, thereby realizing the grinding operation.

It can be appreciated that a deep groove ball bearing is further installed between the rotating shaft 120 and the first mounting groove 114, and the deep groove ball bearing and the unidirectional bearing are arranged at intervals or side by side along the up-down direction, and the deflection of the cup 110 in the rotation process can be reduced by adopting the layout of double bearings, so that the running stability of the cup 110 is improved.

It should be noted that, the controller may also control the knife set 1130 to stir the slurry during the boiling process, that is, the knife set 130 may be used for grinding and crushing, or may be used for stirring, the knife set 1130 may work at different rotation speeds during grinding and stirring, specifically, the rotation speed range of the knife set 130 during crushing is 100 rpm to 3000 rpm, and the rotation speed range of the knife set 130 during stirring is 50 rpm to 200 rpm. For example, after soybean is heated, the soybean is crushed at a rotating speed of 3000 rpm, the ground paste is boiled after the soybean is crushed, and the ground paste is stirred at a rotating speed of 100 rpm during boiling, so that the phenomenon of pasting bottom in the boiling process is avoided, and centrifugal treatment is performed after boiling is completed, so that soybean residues and soybean milk are separated, the pulping effect is good, and the drinking taste is better.

Referring to fig. 12, 13 and 17, it can be understood that the upper end surface of the chassis 113 is provided with a first grinding tooth 1131, the knife set 130 includes a grinding member 131, the lower end surface of the grinding member 131 is provided with a second grinding tooth 1311, when the grinding member 131 rotates, the first grinding tooth 1131 and the second grinding tooth 1311 cooperate with each other to realize grinding, and a grinding channel 140 is formed between the first grinding tooth 1131 and the second grinding tooth 1311, so that the foodstuff is subjected to a grinding force in the up-down direction when passing through the grinding channel 140, and a better grinding effect is obtained. Along the direction of keeping away from chassis 113 center, grinding channel 140 reduces gradually in the clearance of upper and lower direction, and the clearance reduces gradually and can make the foodstuff flow to the in-process all around along the center of chassis 113 under the effect of centrifugal force, realizes the course of coarse grinding gradually, semi-fine grinding to fine grinding for the foodstuff fluid progressively carries out the fine grinding, and then realizes the fine grinding of foodstuff, makes the foodstuff grind finer and more exquisite, has further improved the effect of grinding. Moreover, by adopting a gradual refining grinding mode, the grinding resistance can be effectively reduced, and the smoothness in the grinding process is ensured.

Experiments show that the grinding piece 131 and the chassis 113 in the embodiment of the invention can realize better grinding effect, so that the rotating speed of the motor 210 can be reduced to 6000 rpm or less, the particle size of 95% of foodstuff is smaller than 0.35mm, and the grinding noise can be reduced to about 70 dB.

Referring to fig. 14 and 15, it will be understood that the grinding member 131 includes a connector 1312 and 5 grinding bodies 1313, and of course, 2,3,4 or more grinding bodies 1313 may be provided, which are not specifically limited herein. The plurality of grinding bodies 1313 are connected to the connecting body 1312, respectively, the plurality of grinding bodies 1313 extend along the connecting body 1312 to the peripheral edge of the chassis 113, and the second grinding teeth 1311 are provided on the lower end surface of the grinding bodies 1313, and the grinding bodies 1313 and the chassis 113 cooperate to grind foodstuff. The plurality of grinding bodies 1313 are disposed at intervals along the circumference of the connecting body 1312, and the plurality of grinding bodies 1313 are uniformly disposed along the circumference of the connecting body 1312 and configured to be spirally distributed, so that the plurality of grinding bodies 1313 can squeeze the foodstuff fluid downwards in the rotating process, and guide the foodstuff fluid to enter the grinding channel 140 for grinding, thereby improving the grinding effect. In addition, the inlets are formed between the adjacent grinding bodies 1313, so that the cross-sectional area of the inlet of the grinding channel 140 can be effectively increased, the water flow of the grinding channel 140 is further increased, and the grinding effect is improved.

Referring to fig. 14, it is understood that the abrasive body 1313 includes a spoke portion 1314 and a disk portion 1315, and one end of the spoke portion 1314 is connected to the connecting body 1312 and the other end is connected to the disk portion 1315. The spoke portion 1314 has an arc shape extending in the up-down direction, which increases the contact area between the spoke portion 1314 and the foodstuff fluid, and the abrasion member 131 operates with less resistance, which reduces the power consumption of the motor 210.

Referring to fig. 15, it can be understood that the end edges of the spoke portions 1314 protrude in the rotation direction of the grinding body 1313 so that the end edges are arc-shaped, reducing resistance with the foodstuff fluid; and the edge is provided with a cutting edge, so that the cutting function of foodstuff can be improved, the foodstuff can be further cut before entering the grinding channel 140, and the grinding fineness is improved.

Referring to fig. 15 and 16, it is understood that each disc 1315 is disposed obliquely downward from one end to the other end in the circumferential direction. It should be noted that, the circumferential direction herein may be understood as a movement direction of the disc portion 1315 when the grinding member 131 rotates, and when the rotation direction of the grinding member 131 is clockwise as shown in fig. 15, one end of the disc portion 1315 opposite to the rotation direction is inclined downward toward the other end, and the disc portion 1315 may be partially inclined downward or integrally inclined downward, so that the foodstuff fluid enters the grinding channel 140, and the foodstuff fluid gradually performs fine grinding when passing through the grinding channel 140, thereby realizing fine grinding of foodstuff, making the foodstuff grind finer, further improving the grinding effect, and making the pulping effect better.

Referring to fig. 15, it can be understood that the other end of the disc 1315 extends outwards and protrudes from the spoke 1314, and the disc 1315 protrudes in the opposite direction to the rotation direction of the grinding member 131, i.e., in the counterclockwise direction in fig. 15, so that a gap is formed between the disc 1315 and the spoke 1314, so that the protruding portion of the disc 1315 has a certain elastic deformation, the smoothness of grinding of the disc 1315 is improved, and the phenomenon that the resistance of the grinding member 131 is too large due to the reduction of the grinding channel 140 in the operation process is avoided, so that the grinding member 131 can adapt to grinding of a wider variety of foodstuff.

Referring to fig. 15, it can be understood that the second grinding portion is only provided on the disc portion 1315, and the bottom of the spoke portion 1314 is a smooth surface, so that the grinding effect of the grinding member 131 is ensured and the rotation resistance of the grinding member 131 is reduced.

Referring to fig. 14, 15 and 16, it may be understood that the grinding body 1313 further includes a guide portion 1316, one end of the guide portion 1316 is connected to a peripheral edge of the disc portion 1315, and the other end of the guide portion 1316 is disposed obliquely upward in a direction away from the disc portion 1315, so that a foodstuff fluid at an outlet of the disc portion 1315 can be guided, so that the foodstuff fluid flows out of the guide portion 1316 quickly, thereby accelerating a flow rate of the foodstuff fluid passing through the grinding channel 140, increasing a water flow rate passing through the grinding channel 140, and improving a grinding effect.

Referring to fig. 12 and 13, it will be appreciated that the knife set 130 further includes a top knife 132 and an upper knife 133, the top knife 132 and upper knife 133 being mounted to the shaft 120 by fasteners. The top cutter 132 and the upper cutter 133 cut the foodstuff, so that the foodstuff is further cut before entering the grinding channel 140, the foodstuff is further refined, the subsequent grinding operation is convenient, the grinding fineness is improved, and the pulping effect is better.

Referring to fig. 18 and 19, a cup assembly 100 according to another embodiment of the present invention includes a cup 110, a rotating shaft 120, and a housing 150, where the housing 150 is sleeved outside the cup 110 to wrap the cup 110, and the housing 150 can ensure that a user cannot contact the cup 110 when the cup 110 rotates, so as to avoid injury to the user; but also protects the cup 110, such as from dust. The shell 150 is connected with the cup 110 through a bearing, so that the cup 110 can rotate relative to the shell 150, and the rotation is more stable and smooth.

In addition, in order to avoid interference of the cup 110 with the housing 150 during rotation, a certain gap must be secured between the cup 110 and the housing 150. For example, the gap between the cup 110 and the housing 150 may be 1mm, 2mm or more, and is not particularly limited herein. It will be appreciated that when the gap between the cup 110 and the housing 150 is greater than 1mm, the housing 150 protects the cup 110 without interfering with the rotation of the cup 110 and the overall size of the cup assembly 100 is smaller.

Referring to fig. 12 and 19, it can be appreciated that the lower end of the housing 150 is formed with a second mounting groove 151, the bottom of the cup 110 is downwardly extended to form a rotation post 115, the rotation post 115 is coaxially disposed with the rotation shaft 120, the first mounting groove 114 is formed in the rotation post 115, the second mounting groove 151 and the first mounting groove 114 may be disposed in a cylindrical shape and coaxially disposed with each other, and a one-way bearing is mounted between the rotation post 115 and the second mounting groove 151. It should be noted that, when the rotating shaft 120 rotates along the first direction, the rotating shaft 120 and the cup 110 are interlocked and synchronously rotate, the cup 110 is in rolling connection with the housing 150 through the cooperation of the rotating post 115 and the unidirectional bearing, so as to realize the centrifugal operation of the cup assembly 100; when the rotation shaft 120 rotates along the second direction, the rotation shaft 120 and the cup 110 relatively rotate, the knife set 130 and the cup 110 relatively rotate, and the cup 110 does not rotate under the action of the unidirectional bearing, so that the grinding operation is realized.

It can be appreciated that a deep groove ball bearing is further installed between the rotation post 115 and the second installation groove 151, and the deep groove ball bearing and the unidirectional bearing are arranged side by side or at intervals along the up-down direction, and the deflection of the cup 110 in the rotation process can be further reduced by adopting the layout of double bearings, so that the running stability of the cup 110 is improved, and the interference between the cup 110 and the shell 150 is avoided.

Referring to fig. 20 and 21, it will be appreciated that the cup assembly 100 further includes a cap 160, the cap 160 being removably coupled to the cup 110. The cup cover 160 is used to seal the open end of the cavity 111 when the cup assembly 100 is in a centrifuged or ground state, thereby preventing foodstuff in the cup 110 from overflowing outwards; in addition, in the grinding process of the cup body assembly 100, the cup cover 160 can guide foodstuff to flow back into the cup body 110 to form vortex in the vertical direction, so that more contact exists between the foodstuff and the cutter set 130, and the grinding effect is improved. When the cup body assembly 100 finishes cooking, the cup cover 160 can be opened so as to pour out the cooked slurry, and the operation is convenient; and the inner wall of the cup rim 1121 at the upper end of the cup body 110 is provided with a guiding bevel 1123, so that slurry can be drained, and the slurry can be poured conveniently.

Referring to fig. 20 and 21, it can be appreciated that the cap 160 includes a cap body 161 and a sealing ring 162, the sealing ring 162 is disposed on an outer wall surface of the cap body 161, and the sealing ring 162 is used to seal a gap between the cap body 161 and an inner wall of the cup 110, thereby sealing the cavity 111. Specifically, the sealing ring 162 has a first sealing structure 1621 and a second sealing structure 1622, the first sealing structure 1621 is located below the second sealing structure 1622, the first sealing structure 1621 has a certain gap with a guiding bevel 1123 of the cup body 110 before being closed, in the downward moving process, the guiding bevel 1123 can guide the first sealing structure 1621 into the cup body 110 smoothly, a guiding surface 1623 is formed at the lower end of the first sealing structure 1621, so that the inner wall of the cup body 110 is in transitional connection with the inner wall of the cover body 161, thereby forming a gapless guiding surface 1623 between the sealing ring 162 and the inner wall of the cup body 110, and liquid in the cup can flow back into the cup along the guiding surface 1623, so that no residue exists at the first sealing structure 1621, and cleaning of the cup cover 160 is facilitated.

Referring to fig. 20 and 21, it can be understood that the upper end of the cover 161 is provided with an air outlet 1611, and the air outlet 1611 communicates the cavity 111 with the outside, so that when the food processor 1000 is in a heating function, the air outlet can be used for exhausting air, so that the internal and external air pressures of the cup 110 are balanced, and accidents are avoided.

Referring to fig. 19 and 21, it can be appreciated that the housing 150 includes a housing 152 and a housing cover 153, the housing cover 153 is detachably connected to the upper end of the housing 152, and the housing cover 153 is fixedly connected to the cup cover 160, so that the housing cover 153 and the cup cover 160 can be taken out together, the operation is more convenient, foodstuff is convenient to be added into the cup 110, and slurry in the cup 110 is also convenient to be poured out.

Referring to fig. 19 and 21, it will be appreciated that there is a gap between the cup 110 and the housing 150, and in order to ensure that foodstuff does not enter between the cup 110 and the housing 150 when the cup assembly 100 is pouring and transferring foodstuff of the cup 110, the peripheral wall of the cup 110 is provided with a deflector 116, and the peripheral walls of the deflector 116 are respectively connected with the peripheral wall of the housing 152 and the peripheral wall of the cup 110, thereby closing the gap between the housing 152 and the cup 110. The guide ring 116 is generally made of rubber material with certain elasticity, and is durable and good in sealing performance; and the gap between the housing 152 and the cup 110 can be effectively blocked, so that the slurry can be prevented from entering the gap between the housing 152 and the cup 110 when the food fluid such as the slurry is poured.

It will be appreciated that the cup assembly 100 and the body 200 may be fixedly mounted or detachably connected; of course, the detachable connection mode is adopted, so that the user operation is more convenient, and the experience is better. According to the cooking machine 1000 provided by the embodiment of the invention, the cup body assembly 100 is adopted, the cup body assembly 100 drives the cup body 110 with the containing cavity 111 to rotate through the arrangement of the rotating shaft 120, so that slurry in the containing cavity 111 is contacted with the inner wall of the cup body 110 under the action of centrifugal force, slag in the slurry after centrifugation is adhered to the inner wall of the cup body 110, and the slurry flows back to the bottom of the containing cavity 111, thereby realizing centrifugal filtration of the slurry, having good filtration effect and improving taste; and the slurry after centrifugal separation can be poured out from the opening at the upper end of the container 111, so that the operation is convenient, and the cleaning of the cup body 110 is also more convenient.

Referring to fig. 22, 23 and 24, it can be appreciated that the food processor 1000 further includes a latch assembly 300, and the latch assembly 300 is provided at an upper end of the body 200 for fixing the cup assembly 100 to detachably connect the cup assembly 100 and the body 200. Referring to fig. 19, the cup assembly 100 includes a housing 150 sleeved outside the cup 110, a clamping groove 154 is provided at a lower end of the housing 150, the latch assembly 300 includes a latch 310 matched with the clamping groove 154, and the latch 310 is locked or separated from the clamping groove 154 to fix or separate the cup assembly 100 and the machine body 200, so that a user can conveniently pour slurry in the cup assembly 100 or clean the cup assembly 100, thereby improving convenience of operation of the user.

Referring to fig. 23 and 24, it can be understood that the latch assembly 300 includes a support cover 320, a bottom cover 330 and a latch ring 340 connected to each other, a space for accommodating the latch ring 340 is formed between the support cover 320 and the bottom cover 330, the latch ring 340 is rotatably connected between the support cover 320 and the bottom cover 330, a latch 310 is provided at an upper end of the latch ring 340, and the latch 310 is designed in a '匚' shape with higher strength. Therefore, the user can lock or unlock the latch 310 from the card slot 154 by operating the latch ring 340 to rotate, thereby fixing or separating the cup assembly 100 and the body 200.

Referring to fig. 24, it will be appreciated that the latch assembly 300 further includes a driving mechanism 350, and that the driving mechanism 350 drives the latch ring 340 to rotate, thereby disengaging or locking the body 200 from the cup assembly 100 for convenient operation by a user. It should be noted that, the driving mechanism 350 includes a latch member 351 and a latch handle 352, one end of the latch member 351 is connected to the latch handle 352, the latch handle 352 can drive the latch member 351 to rotate, and the latch handle 352 is located at the outer side of the body 200, so that a user can operate the device conveniently. The other end of the locking piece 351 is provided with a first rack 3511, and the periphery of the locking ring 340 is provided with a second rack 341 meshed with the first rack 3511, so that the locking handle 352 rotates to drive the locking ring 340 to rotate, thereby conveniently realizing locking or separating of the locking buckle 310 and the clamping groove 154, and further realizing fixing or separating of the cup body assembly 100 and the machine body 200.

Referring to fig. 24, it may be appreciated that the supporting cover 320 is provided with a through hole 321 through which the latch 310 passes, the length of the through hole 321 may ensure that the latch 310 may implement positioning guiding from the locking position to the releasing position, the edge of the through hole 321 is provided with a positioning post 322 that is matched with the latch 310, when the latch 310 is in the releasing position, the positioning post 322 supports the latch 310, and may also facilitate positioning between the supporting cover 320 and the housing 150, so as to facilitate assembling the cup assembly 100 and the latch assembly 300.

Referring to fig. 23 and 24, it can be understood that the upper end surface of the support cover 320 is formed with a water guide groove 323 for discharging water dropped on the body 200. Specifically, the bottom wall of the water guide groove 323 is inclined toward the outer periphery of the support cover 320, so that water is conveniently discharged outwards, and the water is prevented from flowing into the machine body 200 to damage parts.

In addition, as shown in fig. 24, the lower end of the support cover 320 is provided with a fixing post 324 for mounting the motor 210, and the motor 210 can be fixed. The supporting cover 320 is fixedly connected with the machine body 200, and can position the lock catch 310 mechanism, and the upper end of the supporting cover 320 supports the cup 110, so that the mounting structure of the machine body 200 is more stable.

Referring to fig. 23, 24 and 27, it can be appreciated that the upper end of the support cover 320 is provided with a cushion pad 325, and the cushion pad 325 is located between the cup assembly 100 and the support cover 320. The cushion pad 325 is generally made of soft rubber material, and the cushion pad 325 can realize the function of buffering between the cup body assembly 100 and the supporting cover 320, thereby avoiding direct contact, reducing vibration transmission and noise; the cushion pad 325 can also realize the function of buffering between the supporting cover 320 and the body 200, avoid direct contact, reduce vibration transmission, and reduce noise; the buffer cushion 325 can also realize that the locking ring 340 keeps a certain locking force when locking the cup 110, preventing loosening; the buffer pad 325 can also waterproof the second electrode 420 to avoid damage to the circuit connection assembly 400.

Referring to fig. 26, it can be understood that the body 200 further includes a motor 210 and a tray 220 disposed up and down, the motor 210 is fixedly connected to the lower end of the latch assembly 300, and synchronous driving is achieved between the motor 210 and the rotating shaft 120 through a coupling. The machine body 200 is provided with an installation cavity, the tray 220 and the motor 210 are positioned in the installation cavity, the tray 220 is fixedly connected in the machine body 200, and the shock pad 230 is arranged between the tray 220 and the lock catch assembly 300, so that the cup assembly 100, the lock catch assembly 300 and the motor 210 are assembled into a rigid body, and a floating connection structure is formed with the machine body 200, so that vibration of the food processor 1000 in a movement process can be reduced, self-balancing of the cup assembly 100 is realized, the balance problem of the cup assembly 100 in a centrifugal process is solved, and stable operation of a complete machine system of the food processor 1000 is ensured. Therefore, the latch assembly 300 is flexibly connected in the up-down, left-right directions, and has a certain degree of freedom, so that the shock absorbing effect of the food processor 1000 is better.

Referring to fig. 26, it may be understood that the tray 220 has a ring structure, and is configured to avoid the motor 210, and a flange 221 is disposed on an inner periphery of the tray 220, and the flange 221 is matched with the shock pad 230 in a positioning manner, so that the shock pad 230 is installed more stably, and a shock absorbing effect is better.

Referring to fig. 25 and 26, it may be appreciated that the machine body 200 further includes a balancing weight 240, the balancing weight 240 is fixedly connected with the motor 210, and the balancing weight 240 may be designed to be annularly wrapped around the periphery of the motor 210 and located at the lower portion of the motor 210, so as to reduce the height dimension of the whole machine 1000, and the center of gravity of the balancing weight 240 is located on the rotation axis of the cup 110, that is, on the center line of the rotation axis 120, so that the center of gravity of the machine 1000 moves downwards, and the left-right deflection of the cup 110 during the rotation motion is reduced, so that the machine 1000 operates more stably and quietly.

Referring to fig. 25 and 27, the heater adopted in the embodiment is a heating plate 170, the heating plate 170 is mounted at the lower end of the chassis 113, the heating plate 170 is used for heating the cavity 111, heating of foodstuff in the cavity 111 is achieved, the grinding effect of the foodstuff is better, and a user can conveniently cook the foodstuff on the food processor 1000, so that functions of the food processor 1000 are richer.

It can be appreciated that the controller can control the heating plate 170 to heat with different heating powers, and can apply different heating powers to different foods, so that the nutritional value of the foods can be ensured, and the pulping effect can be improved. For example, the first heating power is used for heating the foodstuff, the foodstuff is heated to a boiling state, and then the second heating power is used for heating the foodstuff, so that the foodstuff is continuously heated and boiled by the second heating power, wherein the first heating power is greater than or equal to the second heating power, that is, the controller firstly controls the heating disc 170 to heat by high power, and the foodstuff is boiled by low power after boiling, so that the problem of bottom pasting can be effectively avoided, and the pulping effect is improved.

The heating power of the heat generating plate 170 may be selected from 50W to 2500W, for example, the first heating power may be selected from 800W to 2500W, and the second heating power may be selected from 50W to 800W. In addition, heating can be performed in the foodstuff crushing process, for example, in the soybean crushing process, 500W is adopted for heating, crushing is realized while heating, the crushing effect is favorably improved, the prepared soybean milk rate is higher, and the drinking taste is better.

Referring to fig. 27 and 28, in particular, the heat-generating plate 170 is powered by a circuit connection assembly 400. Detailed description referring to the examples shown in figures 6 and 7. The circuit connection assembly 400 includes a first connection mechanism including a first electrode 410, a second connection mechanism including a second electrode 420 mated with the first electrode 410, and a driving device driving the second electrode 420 to be connected to or disconnected from the first electrode 410. Specifically, the first connection mechanism is provided at the bottom of the cup assembly 100, and the second connection mechanism and the driving device are provided on the body 200. The motor 210 drives the rotating shaft 120 to rotate along the second direction, so that when the cutter set 130 can grind foodstuff, the driving device drives the second connecting mechanism to rise, so that the second electrode 420 is connected with the first electrode 410, and at the moment, functional components such as the heating disc 170, a temperature sensor (not shown in the figure) and the like on the cup 110 can be connected, and when the foodstuff is grinded, the foodstuff can be heated simultaneously, thereby saving the time for processing the foodstuff and improving the processing efficiency. The motor 210 drives the cup 110 and the knife set 130 to rotate along the first direction, so that when the slurry and the slag are separated, the driving device drives the second connecting mechanism to descend, and the second electrode 420 is disconnected from the first electrode 410. At this time, the cup 110 drives the first connection mechanism to rotate along the first direction, and since the second electrode 420 is separated from the first electrode 410, the abrasion between the second electrode 420 and the first electrode 410 is reduced, and meanwhile, the resistance of the cup 110 during movement is reduced.

It should be noted that, the driving device may drive the second connection mechanism to move in the up-down direction, and may drive the second connection mechanism to move on the left and right sides, and may also drive the second electrode 420 to be connected to or disconnected from the first electrode 410.

It should be noted that the driving device may also include a linear motor, or the driving device includes a motor and a rack-and-pinion mechanism, so that the effect of driving the second electrode 420 to be connected to or disconnected from the first electrode 410 can be achieved by various existing driving methods.

Referring to fig. 29, 30, 31 and 32, it is understood that the first electrode 410 includes an electrode groove 430 for abutting against the second electrode 420, and the electrode groove 430 is ring-shaped. Since the cup 110 drives the first connection mechanism to rotate, when the first connection mechanism stops rotating, the second electrode 420 and the first electrode 410 may be misplaced, so that the second electrode 420 and the first electrode 410 may be difficult to connect or cannot connect. In this solution, the electrode groove 430 for abutting against the second electrode 420 is disposed on the first electrode 410, and the electrode groove 430 is annular, so that after the first connection mechanism stops rotating, the second electrode 420 and the first electrode 410 can still be accurately connected, and the position does not need to be calibrated again, thereby improving the working efficiency and the user experience.

Referring to fig. 29, 30 and 31, it can be understood that the first connection mechanism further includes an electrode cover 440, the electrode cover 440 is provided with a third mounting groove, the first electrode 410 is disposed in the third mounting groove, and the electrode cover 440 is connected to the cup 110. Referring to fig. 30, the difference in height between the end surface of the third mounting groove and the end surface of the electrode groove 430 is h, which is greater than 0.5mm. It can also be understood that, after the first electrodes 410 are mounted in the third mounting groove, the sidewall of the third mounting groove is higher than the sidewall of the electrode groove 430 by a distance h, which is greater than 0.5mm, to increase the creepage distance between two adjacent first electrodes 410. Creepage distance refers to the charging area between two conductive parts measured along the insulating surface, which, under different usage conditions, is a charging phenomenon due to the insulating material around the conductor being electrically polarized.

Referring to fig. 30, it will be appreciated that the first electrode 410 is provided with a screw post 411, the electrode cap 440 is provided with a screw via 441, and the first electrode 410 is coupled to the electrode cap 440 by a screw (not shown), i.e., the screw is screwed to the electrode cap 440 after passing through the screw via 441, thereby fixing the first electrode 410 to the electrode cap 440. It should be noted that the first electrode 410 may also be connected to the electrode cover 440 by a structure such as a buckle, a pin, or the like.

It should be noted that, the beverage preparation method of the above embodiment is implemented by controlling the food processor 1000 to cook food, for example, the method step S100 in fig. 1, the method steps S110 to S120 in fig. 2, the method steps S130 to S150 in fig. 3, and the like described in the above embodiment are performed. Specifically, the controller controls the motor 210 to drive the knife set 130 to rotate, so as to grind, crush and stir foodstuff, controls the motor 210 to drive the cup 110 to rotate, generates centrifugal force to enable the material slag in the slurry to adhere to the inner wall of the cup 110, realizes separation of the material slag and the slurry, and controls the heating disc 170 to heat, etc. Compared with the existing food processor, the centrifugal type is adopted to separate the material slag from the slurry, manual operation is not needed for filtering, the separation effect is better and more efficient, the centrifugal type food processor can be suitable for making beverages such as fruit juice, soybean milk and the like, and the separation of the material slag from the slurry realizes mechanization, so that the slurry has better drinking taste.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present invention.

Claims (13)

1. The beverage preparation method is characterized by being applied to a food processor with a rotatable container, wherein the container comprises a cup body, the food processor comprises a driving device, the cup body comprises an upper cup body and a chassis, the upper cup body and the chassis are mutually connected and are arranged up and down, the joint of the upper cup body and the chassis is a first cross section, the cross section area of the upper cup body is gradually reduced upwards from the first cross section, the cross section area of the chassis is gradually reduced downwards from the first cross section, the cup body is provided with a cutter set and a rotating shaft, the rotating shaft is connected with the cup body through a one-way bearing, the cutter set is connected with the rotating shaft, the driving device is used for driving the cutter set and the container to rotate, and the driving device comprises a motor, and the motor is connected with the rotating shaft through a coupling; the upper end face of the chassis is provided with first grinding teeth, the cutter set comprises a grinding piece, the lower end face of the grinding piece is provided with second grinding teeth, and the method comprises the following steps:

When the rotating shaft rotates along the second direction, the rotating shaft drives the cutter group to rotate relative to the cup body, the first grinding teeth and the second grinding teeth are matched with each other to grind, and foodstuff in the container is crushed to obtain slurry;

When the rotating shaft rotates along a first direction, the rotating shaft drives the cup body to rotate, the cutter group and the cup body synchronously move, and the first direction is opposite to the second direction so as to rotate the container loaded with slurry to perform centrifugation, so that at least part of material residues in the slurry are adhered to the inner wall of the cup body, and the slurry can flow back to the bottom of the cup body, so that the material residues are separated.

2. The beverage preparation method according to claim 1, wherein the beverage preparation method further comprises:

heating the foodstuff to a boiling state with a first heating power, and then boiling the foodstuff with a second heating power;

Wherein the first heating power is greater than or equal to the second heating power.

3. The beverage preparation method according to claim 2, wherein the step of crushing the foodstuff within the container is performed after the heating of the foodstuff to a boiling state with a first heating power.

4. The beverage preparation method according to claim 2, wherein the first heating power is 800W to 2500W and the second heating power is 50W to 800W.

5. The beverage preparation method according to any one of claims 1 to 4, wherein the foodstuff comprises soy and water, the method comprising:

Crushing the soybeans in the container to obtain soybean milk;

And when the container is rotated for centrifugation, at least part of bean dregs are adhered to the inner wall of the container.

6. The beverage preparation method according to claim 5, wherein the weight ratio of soybean to water is 1:2 to 1:15.

7. The beverage preparation method according to claim 1, further comprising:

the slurry is heated prior to centrifuging the rotating slurry-laden vessel.

8. The beverage preparation method according to claim 1, wherein said heating the slurry comprises:

the slurry is stirred during heating, and the stirring speed is 50-200 rpm.

9. The beverage preparation method according to claim 1, wherein the rotation speed of the container is 500 to 5000 rpm and the centrifugation time is 0.5 to 10 minutes when the container loaded with the slurry is rotated for centrifugation.

10. The method of preparing a beverage according to claim 1, wherein said crushing the foodstuff in the container comprises:

the foodstuff is crushed by means of a knife set with a rotation speed of 100 rpm to 3000 rpm for a crushing time of 0.2 min to 3 min.

11. A cooking machine, characterized by comprising:

The device comprises a container, wherein the container is used for loading slurry, a cutter set is arranged in the container, the container comprises a cup body, the cup body comprises an upper cup body and a bottom plate, the upper cup body and the bottom plate are connected with each other and are arranged vertically, the joint of the upper cup body and the bottom plate is a first cross section, the cross section area of the upper cup body gradually decreases upwards from the first cross section, the cross section area of the bottom plate gradually decreases downwards from the first cross section, the cup body is provided with the cutter set and a rotating shaft, the rotating shaft is connected with the cup body through a one-way bearing, the cutter set is connected with the rotating shaft, the upper end face of the bottom plate is provided with first grinding teeth, the cutter set comprises a grinding piece, and the lower end face of the grinding piece is provided with second grinding teeth;

the driving device is used for driving the container and the cutter group to rotate and comprises a motor, and the motor is connected with the rotating shaft through a coupler;

The controller is used for controlling the driving device to drive the cutter set and the container to rotate, when the rotating shaft rotates along the second direction, the rotating shaft drives the cutter set to rotate relative to the cup body, and the first grinding teeth and the second grinding teeth are matched with each other to grind so as to crush foodstuff in the container to obtain the slurry; when the rotating shaft rotates along a first direction, the rotating shaft drives the cup body to rotate, the cutter group and the cup body synchronously move, and the first direction is opposite to the second direction so as to rotate the container loaded with slurry to perform centrifugation, so that at least part of material residues in the slurry are adhered to the inner wall of the cup body, and the slurry can flow back to the bottom of the cup body, so that the material residues are separated.

12. The food processor according to claim 11, wherein the inner wall inclination angle of the cup body is alpha, and the alpha is 90 degrees > alpha is more than or equal to 60 degrees.

13. The food processor of claim 11, further comprising a heater, wherein the controller controls the heater to heat the foodstuff;

The controller also controls the heater to boil the foodstuff with a second heating power after heating the foodstuff to a boiling state with a first heating power, wherein the first heating power is greater than or equal to the second heating power.