CN220824179U - Stirring cup assembly and cooking machine - Google Patents

Abstract

The application discloses a stirring cup assembly and a cooking machine. The stirring cup assembly comprises a cup body assembly and an inner cover assembly. The cup assembly includes a cup and a blade. The blade is rotationally assembled in the cup body. The inner cover assembly comprises a cover body and a partition plate, wherein the inside of the cover body is divided into a first cavity and a second cavity by the partition plate, and the first cavity and the second cavity are respectively provided with an opening and the directions of the openings are opposite. The inner cover assembly is detachably assembled in the cup body, the inner cover assembly can be positively placed or reversely placed in the cup body under the condition that the inner cover assembly is assembled in the cup body, the first cavity and the cup body enclose a first stirring cavity under the condition that the inner cover assembly is positively placed, and the blade is positioned in the first stirring cavity; under the condition of inverted placement, the second cavity and the cup body enclose a second stirring cavity, and the blade is positioned in the second stirring cavity. Therefore, whether the inner cover assembly is used or not can be selected according to the amount of the food materials, so that the capacity matched with the amount of the food materials is obtained, and the user experience is improved.

Description

Stirring cup assembly and cooking machine

Technical Field

The application relates to the technical field of small household appliances, in particular to a stirring cup assembly and a cooking machine.

Background

At present, food processors on the market, such as a stirrer, a juicer, a wall breaking machine and the like, comprise a stirring cup. The volume of the stirring cup is fixed. If more food is contained, but the capacity of the stirring cup is smaller, under the condition that the stirring knife is used for stirring at high speed, the food which is not completely chopped is thrown out and stuck on the wall of the stirring cup or the inner wall of the cup cover, so that the phenomenon of uneven stirring and chopping of the food is easy to occur; when the food materials are less and the capacity of the stirring cup is larger, the food materials cannot be crushed more effectively due to the large space, for example, when a user wants to stir and crush some dry food materials or medicinal materials, the food materials cannot be crushed due to the large space, and the user needs to replace the dry grinding cup with a small capacity for crushing.

In summary, the fixed capacity of the stirring cup brings inconvenience to use and the user experience is poor.

Disclosure of utility model

The application aims to provide a stirring cup assembly and a cooking machine. The capacity of cooking machine is adjustable, applicable multiple food crushing scene, convenient to use, user experience is good.

The application provides a stirring cup assembly. The stirring cup assembly comprises a cup body assembly and an inner cover assembly, wherein: the cup assembly includes a cup and a blade. The blade is rotationally assembled in the cup body. The inner cover assembly comprises a cover body and a partition plate, wherein the inner part of the cover body is divided into a first cavity and a second cavity by the partition plate, and the first cavity and the second cavity are respectively provided with an opening and the directions of the openings are opposite. The inner cover assembly is detachably assembled in the cup body, the inner cover assembly can be placed in the cup body in a forward or reverse mode under the condition that the inner cover assembly is assembled in the cup body, a first stirring cavity is formed by the first cavity and the cup body in a surrounding mode under the forward placing condition, and the blade is positioned in the first stirring cavity; under the condition of inverted placement, the second cavity and the cup body enclose a second stirring cavity, and the blade is positioned in the second stirring cavity.

In the above arrangement, since the inner cover assembly is detachably assembled in the cup body, the capacity of the stirring cup assembly is the capacity a of the cup body when the inner cover assembly is not assembled in the cup body; under the condition that the inner cover component is assembled in the cup body, according to the forward or backward placement condition of the cover component, the capacity of the stirring cup component can be the capacity b of the first stirring cavity or the capacity c of the second stirring cavity, so that whether the inner cover component is used or not (namely, the capacity of the food processor is adjustable) can be selected according to the amount of food materials, the capacity is matched with the amount of the food materials, the condition that a small amount of food materials are stirred in a large capacity space and a large amount of food materials are stirred in a small capacity space is avoided, and the user experience is improved. Of course, the volume of the first cavity and the volume of the second cavity may be equal, at this time, the capacity b=capacity c, and the stirring cup assembly has two capacities, which also can be used conveniently. In other embodiments, under the condition that the volume of the first cavity is unequal to the volume of the second cavity, the capacity b is unequal to the capacity c, so that the stirring cup assembly has three capacities, is suitable for different food material crushing scenes, and is more convenient for the use of the inner cover assembly.

In some embodiments, the mixing cup assembly includes a first one-way communication and a second one-way communication; under the condition that the inner cover assembly is placed in the normal position, the first stirring cavity is communicated with the outside of the stirring cup assembly only through the first one-way communicating piece; under the condition that the inner cover assembly is placed upside down, the second stirring cavity is communicated with the outside of the stirring cup assembly only through the second one-way communicating piece.

As the setting, through the outside of first one-way intercommunication piece or second one-way intercommunication piece intercommunication stirring cup subassembly, from this, first one-way intercommunication piece or second one-way intercommunication piece can be used for reducing or reduce and use the corresponding formation of inner cover subassembly first stirring chamber and second stirring chamber in-process air pressure difference improves dismouting inner cover subassembly difficulty, simultaneously because first stirring chamber is outside only through first one-way intercommunication piece intercommunication stirring cup subassembly, prevents to stir food material in-process, and food material overflows to the second cavity, and the second stirring chamber is outside only through second one-way intercommunication piece intercommunication stirring cup subassembly, can prevent that food material from overflowing to first cavity.

In some embodiments, the separator is provided with a first vent and a second vent; the first one-way communication member opens or closes the first exhaust hole; the second one-way communication opens or closes the second exhaust hole.

As the first unidirectional communicating piece and the second unidirectional communicating piece are arranged on the partition board, and the first exhaust hole and the second exhaust hole are arranged on the partition board, the first unidirectional communicating piece opens or closes the first exhaust hole; the second one-way communication opens or closes the second exhaust hole. In this way, the construction of the inner housing assembly is simpler. During assembly of the inner housing assembly, gas is more easily exhausted from the corresponding first or second exhaust holes.

In some embodiments, the first cavity and the second cavity each taper from the respective opening in a direction toward the partition.

As the first cavity and the second cavity are gradually reduced from the respective openings to the direction of the partition plate, no matter the inner cover assembly is put forward or put backward, the food material falls down from a large space to a small space in the stirring process, and the turbulence effect is good. Furthermore, the inner cover with the structure is convenient to manufacture.

In some embodiments, the volume of the first cavity and the volume of the second cavity are not equal.

As the volume of the first cavity is unequal to the volume of the second cavity, the stirring cup assembly can have more capacity, and user experience is better.

In some embodiments, the baffle is integrally formed with the cover.

In the arrangement, the baffle plate and the cover body are integrally formed, so that the cover body and the baffle plate are convenient to manufacture.

In some embodiments, the partition may be removably mounted to the housing at different locations to correspondingly vary the volume of the first cavity and the volume of the second cavity.

As mentioned above, the partition board can be detachably arranged at different positions of the cover body to change the volume of the first cavity and the volume of the second cavity, so that more capacity can be obtained under the condition of using the inner cover component, the partition board can be suitable for food materials with various capacities, and the user experience is further improved.

In some embodiments, the stirring cup assembly includes a cup cover assembly, the cover including opposite ends; under the condition that the cup cover assembly is locked with the cup body assembly, one end portion of the cover body is abutted against the cup body, and the other end portion of the cover body is abutted against the cup cover assembly.

As the arrangement is that one end of the cover body is abutted against the cup body, the other end of the cover body is abutted against the cup cover assembly, so that the inner cover assembly is not easy to loosen, and after the cup cover assembly and the cup body assembly are locked, the inner cover assembly can be fixed, and the inner cover assembly is simple in structure and convenient to fix.

In some embodiments, a seal is disposed between one end of the cap and the cup and between the other end of the cap and the cap assembly.

By arranging the sealing element to absorb shock of the inner cover assembly and seal the corresponding first stirring cavity or the second stirring cavity, noise generated when the blade is stirred can be effectively reduced, and food leakage can be avoided.

In some embodiments, the cap assembly includes a cap body and a surrounding bone disposed on the cap body; one end of the inner cover is abutted against the cover body and is covered by the surrounding bone.

The combined action of the cover body and the surrounding bone ensures that one end part of the cover body cannot shake in the vertical direction and the horizontal direction, and the structure is easier to fix one end part of the cover body.

In some embodiments, the cup wall of the cup body is provided with a turbulence bar and a step connected with the turbulence bar; the two ends of the cover body are provided with notches, the turbulence ribs are correspondingly clamped in the notches one by one under the condition that the inner cover assembly is placed forward, and the end part positioned at one side of the first cavity is abutted against the step so as to seal the first stirring cavity; under the condition that the inner cover component is placed upside down, the turbulence ribs are clamped in the gaps in a one-to-one correspondence mode, and the end portions located on one side of the second cavity are abutted to the steps to seal the second stirring cavity.

Through the gap with the cooperation of vortex muscle, and, the tip with the cooperation of step, not only convenient with the inner cover subassembly is fixed so that the inner cover subassembly can not rotate at the circumference of cup, and after the bowl cover subassembly equipment, the inner cover subassembly can not the drunkenness in vertical direction, thereby, the fixed simple and firm of inner cover subassembly also is convenient for seal first stirring chamber or second stirring chamber.

In another aspect, an embodiment of the application discloses a food processor. The food processor comprises a main machine and any one of the stirring cup assemblies, wherein the main machine comprises a motor, and the motor drives the blade to rotate.

As set forth above, the food processor has the beneficial effects of the stirring cup assembly at least and will not be described again.

Drawings

Fig. 1 is a perspective view of a food processor according to an embodiment of the present application;

fig. 2 is an exploded view of the food processor shown in fig. 1;

FIG. 3 is a cross-sectional view of the blender cup assembly of the food processor of FIG. 1, shown without the inner cover assembly installed;

FIG. 4 is a partial cross-sectional view of the food processor shown in FIG. 1, illustrating the inner housing assembly in place;

FIG. 5 is a schematic view of the remaining portion of the article taken in the plane of line A-A of FIG. 4;

FIG. 6 is a cross-sectional view of the blender cup assembly of the disposer of FIG. 1, illustrating the inverted placement of the inner housing assembly;

FIG. 7 is a schematic view of an inner shroud assembly according to an embodiment of the present application;

Fig. 8 is a top view of the inner housing assembly shown in fig. 7.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus consistent with aspects of the application as detailed in the accompanying claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The terms "first," "second," and the like in the description and in the claims, are not used for any order, quantity, or importance, but are used for distinguishing between different elements. Likewise, the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. "plurality" or "plurality" means two or more. Unless otherwise indicated, the terms "front," "rear," "lower," and/or "upper" and the like are merely for convenience of description and are not limited to one location or one spatial orientation. The word "comprising" or "comprises", and the like, means that elements or items appearing before "comprising" or "comprising" are encompassed by the element or item recited after "comprising" or "comprising" and equivalents thereof, and that other elements or items are not excluded. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any or all possible combinations of one or more of the associated listed items.

Referring to fig. 2, 3, 4, 5 and 6, an embodiment of the present application discloses a blender cup assembly 10. The mixing cup assembly 10 includes a cup body assembly 1 and an inner cup assembly 2. The cup assembly 1 includes a cup 11 and a blade 12. The blade 12 is rotatably assembled in the cup 11. In fig. 3, 4, 5 and 6, the cup 11 includes a cup wall 111 and a cup bottom 112. The cup bottom 112 and the cup wall 111 are integrally formed, and the cup bottom 112 serves as a cutter head. In other embodiments, the bottom 112 may be a separate component, such as a cutter head, and the bottom 112 may be assembled with the wall 111 to form the cup 11, such as by locking the base 14 with the wall 111 to clamp the rim of the bottom 112 between the wall 111 and the base 14 and assembling the bottom 112 to the wall 111. The structure of the blade 12 assembled to the cup bottom 112 is not limited, for example, the blade 12 is assembled to a cutter shaft, the cutter shaft is inserted into a bearing assembly, and the bearing assembly is assembled to the cup bottom 112 to realize the rotation of the blade 12 and is assembled to the cup bottom 112.

Referring to fig. 2, 3, 4, 5 and 6, the inner housing assembly 2 includes a housing body 21 and a partition 22. The separator 22 may be integrally formed with the cover 21 as shown in the drawing, or may be incorporated into the cover 21 as a separate member. The partition 22 partitions the inside of the cover 21 into a first cavity 211 and a second cavity 212. The first cavity 211 and the second cavity 212 have openings respectively and the openings are opposite in direction, see fig. 7, the opening of the first cavity 211 is vertically downward, and the opening of the second cavity 212 is vertically upward.

The inner cover assembly 2 is detachably assembled in the cup body, and fig. 3 illustrates that the inner cover assembly 2 is not assembled in the cup body 11. Fig. 4 and 5 illustrate the inner cup assembly 2 assembled in the cup 11, being placed in the cup 11. Fig. 6 illustrates the inner cup assembly 2 assembled in the cup 11, inverted into the cup 11. In the case that the inner cover assembly 2 is being placed, the first cavity 211 and the cup 11 define a first stirring cavity 213, specifically, an opening of the first cavity 211 is covered by a corresponding portion of the cup 11 to define the first stirring cavity 213, and in fig. 4 and 5, the first cavity 211 is covered by a portion of the cup wall 111 and the cup bottom 112 to define the first stirring cavity 213. In other embodiments, only the bottom 112 may cover the first cavity 211 to define the first stirring chamber 213. The blade 12 is positioned within the first stir chamber 213. In the case of the inverted placement of the inner cover assembly 2, the second cavity 212 and the cup 11 enclose a second stirring cavity 214, specifically, the opening of the second cavity 212 is covered by the corresponding portion of the cup 11 to enclose a second stirring cavity 214, and in the case of the inverted placement, the blade 12 is located in the second stirring cavity 214. In fig. 6, the second cavity 212 is covered by a portion of the cup wall 111 and the cup bottom 112 to enclose a second stir chamber 214. In other embodiments, it is also possible that only the cup bottom 112 covers the second cavity 212 to enclose the second stir chamber 214.

In the above arrangement, since the inner cover assembly 2 is detachably assembled in the cup body, the capacity of the stirring cup assembly is the capacity a of the cup body 11 when the inner cover assembly 2 is not assembled in the cup body; under the condition that the inner cover assembly 2 is assembled in the cup 11, according to the forward or backward placement of the cover assembly, the capacity of the stirring cup assembly can be the capacity b of the first stirring cavity 213 or the capacity c of the second stirring cavity 214, so that whether the inner cover assembly 2 is used or not can be selected according to the food amount (that is, the capacity of the food processor is adjustable), the capacity is matched with the food amount, the problem that a small amount of food uses a large capacity space for stirring (such as a small amount of large capacity space for stirring can be avoided, which can cause poor stirring and chopping effects, for example, a dry grinding function can be realized), the condition that a large amount of food uses a small capacity space for stirring (such as a large amount of food uses a small space for stirring, which can cause the food to be adhered to the cup wall 111) can be avoided, and the user experience is improved. Of course, the volume of the first cavity 211 and the volume of the second cavity 212 may be equal, and at this time, the volume b=the volume c, and the mixing cup assembly 10 may have two volumes, which is convenient for use, and in this case, the inner cover assembly 2 may be placed in a forward or reverse manner, so that the inner cover assembly 2 is convenient for use. In other embodiments, in the case that the volume of the first cavity 211 and the volume of the second cavity 212 are not equal, the capacity b is not equal to the capacity c, so that the mixing cup assembly 10 has three capacities, and can be suitable for various food material crushing scenes, and the inner cover assembly 2 is more convenient to use. In addition, the cover body 21 of the inner cover assembly 2 comprises a first cavity 211 and a second cavity 212, and the inner cover assembly 2 can be used as a measuring cup or a container, so that the functions of the inner cover assembly 2 are expanded.

Referring to fig. 7 and 8 in combination with fig. 4, 5 and 6, the blender cup assembly includes a first one-way communication member 23 and a second one-way communication member 24. Referring to fig. 4 and 5, in the case where the inner cup assembly 2 is being placed, the first stirring chamber 213 communicates with the outside of the stirring cup assembly 10 only through the first one-way communication member 23, and the second one-way communication member 24 is closed. In the case where the inner cup assembly 2 is put upside down, the second stirring chamber 214 communicates with the outside of the stirring cup assembly 10 only through the second one-way communication member 24, and the first one-way communication member 23 is closed. The way of communicating the outside of the stirring cup assembly 10 is not limited to the embodiment described later, and the pressure may be released by communicating the outside based on the action described later.

As set forth above, the first one-way communication member 23 or the second one-way communication member 24 is communicated with the outside of the mixing cup assembly 10, so that the first one-way communication member 23 or the second one-way communication member 24 can be used for reducing or lowering the air pressure difference between the first mixing chamber 213 and the second mixing chamber 214 when the inner cover assembly 2 is used, thereby improving the problem of difficulty in assembling and disassembling the inner cover assembly 2, and simultaneously, since the first mixing chamber 213 is communicated with the outside of the mixing cup assembly 10 only through the first one-way communication member 23, the food material can be prevented from overflowing to the second cavity 212 in the process of mixing the food material, and the second mixing chamber 214 is communicated with the outside of the mixing cup assembly 10 only through the second one-way communication member 24, thereby preventing the food material from overflowing to the first cavity 211.

The skilled person will appreciate that, based on the foregoing actions (which may be understood as pressure relief) of the first one-way communication member 23 and the second one-way communication member 24, the arrangement position of the first one-way communication member 23 and the second one-way communication member 24, the structure of the mixing cup assembly to be matched therewith, and the like are not limited, and the actions may be achieved.

The following describes the structure employed in the embodiment of the present application.

Referring to fig. 7 and 8 in combination with fig. 4, 5 and 6, the first and second one-way communication members 23 and 24 are both one-way valves, and of course, as previously described, are not limited thereto. In the present embodiment, the first one-way communication piece 23 and the second one-way communication piece 24 are both provided to the partition 22. The partition 22 is provided with a first vent hole 221 and a second vent hole (only the first vent hole 221 is visible in fig. 8 because the gas flowing directions of the first one-way communication piece 23 and the second one-way communication piece 24 are different). The first one-way communication member 23 opens or closes the first exhaust hole 221; the second one-way communication 24 opens or closes the second exhaust hole. How to open or close is achieved by various structures, see fig. 7 and 8 in combination with fig. 4 and 6, two through holes are provided in the partition 22, and the first one-way communication member 23 and the second one-way communication member 24 include a sealing portion 231 and an assembling portion 232, respectively. The respective assembling portions 232 are assembled with one through hole and form a reverse buckle, so that the respective sealing portions 231 can seal the respective exhaust holes, and the respective exhaust holes are opened by the air pressure difference.

As set forth above, since the first one-way communication member 23 and the second one-way communication member 24 are provided to the partition 22, and the partition 22 is provided with the first exhaust hole and the second exhaust hole, the first one-way communication member 23 opens or closes the first exhaust hole 221; the second one-way communication 24 opens or closes the second exhaust hole. In this way, the structure of the inner cover assembly 2 is simpler. During assembly of the inner cap assembly 2, gas is more easily discharged from the corresponding first or second gas discharge hole 221 or 221.

Referring to fig. 7 in combination with fig. 4, 5 and 6, the first cavity 211 and the second cavity 212 are respectively tapered from their respective openings in the direction of the partition 22. In fig. 7, the first cavity 211 is gradually reduced in a vertically upward direction, and the second cavity 212 is gradually reduced in a vertically downward direction.

As the first cavity 211 and the second cavity 212 are gradually reduced from the respective openings to the direction of the partition 22, the food material falls down from a large space to a small space during the stirring process, and the turbulence effect is good, regardless of whether the inner cover assembly 2 is being placed in the normal direction or the inner cover assembly 2 is being placed in the reverse direction. Furthermore, the cover 21 having the above-described structure is also easy to manufacture.

Referring to fig. 7, the partition 22 is integrally formed with the cover 21.

As described above, since the partition 22 is integrally formed with the cover 21, the cover 21 and the partition 22 are easily manufactured.

In the above embodiment, the partition 22 is installed at a fixed position in the cover 21, so that the stirring cup assembly 10 can have only several capacities of the capacity a, the capacity b and the capacity c. To allow for more capacity, in some embodiments, the baffle 22 can be removably mounted to the housing 21 at different locations to correspondingly change the volume of the first cavity 211 and the volume of the second cavity 212. As for the structure for realizing the mounting of the partition plate 22 at different positions in the housing 21, any structure may be adopted, for example, ribs or the like spaced in the vertical direction may be adopted, and the partition plate 22 is detachably mounted at different positions by being caught by different ribs. For another example, the side wall of the cover 21 is provided with grooves spaced in the vertical direction, the partition 22 is provided with telescopic members, when the partition 22 is installed, the telescopic members are abutted against the side wall to shrink, when the telescopic members are aligned with the grooves, the telescopic members extend into the grooves, and thus, the partition 22 is matched with the grooves with different heights to be installed at different positions of the cover 21.

As set forth above, the partition 22 is detachably mounted at different positions of the cover 21 to change the volume of the first cavity 211 and the volume of the second cavity 212, so that the stirring cup assembly can have a larger capacity when the inner cover assembly 2 is used, and can be applied to food materials having various capacities, thereby further improving user experience.

Any structure may be used in the inner cover assembly 2, such as how to prevent shaking in the cup 11 during use, for example, two ends 225 of the cover 21 are respectively abutted against the cup 11 (for example, one end is abutted against the bottom of the cup, and the other end is abutted against the wall of the cup). As follows, referring to fig. 7 and 8 in conjunction with fig. 4, 5 and 6, one embodiment is described as follows:

As shown in fig. 7 and 8, the blender cup assembly includes a cup lid assembly 3. The housing 21 includes opposite ends 215. With the lid assembly 3 locked to the cup assembly 1, one end 215 of the cap 21 abuts the cup 11 and the other end 215 of the cap 21 abuts the lid assembly 3. The locking structure between the cup cover assembly 3 and the cup body assembly 1 is not limited. As to the portion abutting the cup 11, in embodiments of the present application, the end 215 abuts the wall 111 of the cup 11, and in some embodiments, the end 215 may abut the bottom 112.

As the above arrangement, since the one end 215 of the cover 21 abuts against the cup 11, the other end 215 of the cover 21 abuts against the cap assembly 3, so that the inner cap assembly 2 is not easy to loosen, and the cap assembly 3 and the cup assembly 1 are locked, the inner cap assembly 2 can be fixed, and the inner cap assembly 2 is fixed with simple structure and convenient fixing.

Referring to fig. 4, 5, 6 and 7, in some embodiments, a sealing member 4 is disposed between one end 215 of the cover 21 and the cup 11, and between the other end 215 of the cover 21 and the cap assembly 3, and the sealing member 4 dampens and seals the corresponding first stirring chamber 213 or second stirring chamber 214 of the inner cover assembly 2, that is, when the inner cover assembly 2 is being placed in the normal position, one sealing member 4 seals the first stirring chamber 213, and when the inner cover assembly 2 is being placed in the reverse position, the other sealing member 4 seals the second stirring chamber 214.

By arranging the sealing member 4 to dampen and seal the corresponding first stirring cavity 213 or the second stirring cavity 214 of the inner cover assembly 2, the noise generated when the blade 12 is stirred can be effectively reduced, and the food can be prevented from leaking.

Based on the above-mentioned function of the lid assembly 3 against the inner cap assembly 2, the structure of the inner cap assembly 2 is not limited, and in the embodiment of the application, referring to fig. 6, the lid assembly 3 includes a lid 31 and a surrounding rib 32 disposed on the lid 31. One end 215 of the cover 21 abuts against the cover 31 and is covered by the surrounding bone 32. Based on the effect of the surrounding ribs 32, the surrounding ribs 32 can be one circle or can be distributed at intervals in the circumferential direction of the cup cover assembly 3.

As set forth above, the cooperation of the cover 31 and the surrounding rib 32 prevents the one end 215 of the cover 21 from shaking in both the vertical and horizontal directions, and the structure also makes it easier to fix the one end 215 of the cover 21.

Referring to fig. 3, in some embodiments, the cup wall 111 of the cup 11 is provided with a spoiler 1111 and a step 1112. The step 1112 is connected to the spoiler 1111. Referring to fig. 7 and 8, the end portions 215 of the cover 21 are each provided with a notch 2151, in which the end portions 215 include end edges 2152 and the notches 2151 are located between the end edges 2152. Referring to fig. 5, in the case that the inner cover assembly 2 is being placed, the spoiler 1111 is correspondingly clamped to the notch 2151, and the end 215 located at one side of the first cavity 211 abuts against the step 1112, in the figure, the end edge 2152 of the end 215 abuts against the step 1112 to seal the first stirring cavity 213, in combination with the arrangement of the first unidirectional communicating member 23, the first stirring cavity 213 is only communicated with the second cavity 212 through the first unidirectional communicating member 23, and in the case that the cup cover assembly 3 is not locked, the second cavity 212 is communicated with the outside of the stirring cup assembly, so that, in the case that the inner cover assembly 2 is being placed, the gas in the first stirring cavity 213 can be discharged out of the stirring cup assembly through the first unidirectional communicating member 23 and the second cavity 212.

Referring to fig. 6, when the inner cover assembly 2 is placed upside down, the spoiler 1111 is correspondingly locked to the notch 2151, and an end portion located at one side of the second cavity 212 abuts against the step 1112, as shown in the figure, an end edge 2152 of the end 215 abuts against the step 1112, so as to seal the second stirring cavity 214. Thus, in combination with the arrangement of the second one-way communication member 24, the second stirring cavity 214 is communicated with the first cavity 211 only through the second one-way communication member 24, and the first cavity 211 is communicated with the outside of the stirring cup assembly under the condition that the cup cover assembly 3 is not locked, so that the gas in the second stirring cavity 214 can be discharged out of the stirring cup assembly through the second one-way communication member 24 and the first cavity 211 under the condition that the inner cover assembly 2 is reversely placed.

Through the cooperation of the notch 2151 and the spoiler 1111 and the cooperation of the end 215 and the step 1112, the inner cover assembly 2 is not only conveniently fixed so that the inner cover assembly 2 cannot rotate in the circumferential direction of the cup 11, but also the inner cover assembly 2 cannot move in the vertical direction after the cup cover assembly 3 is assembled, so that the inner cover assembly 2 is simply and firmly fixed, and the first stirring cavity 213 or the second stirring cavity 214 is also conveniently sealed.

Referring to fig. 1, 2 and 4, an embodiment of the present application discloses a food processor. The food processor comprises a main machine 20 and any stirring cup assembly 10, wherein the main machine 20 comprises a motor, and the motor drives the blade 12 to rotate.

As set forth above, the food processor has the beneficial effects of the stirring cup assembly at least and will not be described again.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the application.

Claims (10)

1. The utility model provides a stirring cup assembly, its characterized in that, stirring cup assembly includes cup subassembly (1) and inner cover subassembly (2), wherein:

The cup body assembly (1) comprises a cup body (11) and a blade (12), wherein the blade (12) is rotationally assembled in the cup body (11);

The inner cover assembly (2) comprises a cover body (21) and a baffle plate (22), wherein the interior of the cover body (21) is divided into a first cavity (211) and a second cavity (212) by the baffle plate (22), and the first cavity (211) and the second cavity (212) are respectively provided with openings with opposite opening directions;

The inner cover component (2) is detachably assembled in the cup body (11); the inner cover assembly (2) can be placed in the cup body (11) in a forward or reverse mode under the condition that the inner cover assembly (2) is assembled in the cup body (11), a first stirring cavity (213) is formed by the first cavity (211) and the cup body (11) in a surrounding mode under the forward placement mode, and the blade (12) is located in the first stirring cavity (213); in the inverted condition, the second cavity (212) and the cup body (11) enclose a second stirring cavity (214), and the blade (12) is positioned in the second stirring cavity (214).

2. A mixing cup assembly according to claim 1, wherein the mixing cup assembly comprises a first unidirectional communication (23) and a second unidirectional communication (24);

-said first stirring chamber (213) communicates with the outside of said stirring cup assembly only through said first unidirectional communication (23) with said inner cap assembly (2) being in the forward position;

With the inner cap assembly (2) inverted, the second stir chamber (214) communicates with the exterior of the stir cup assembly only through the second one-way communication (24).

3. A stirring cup assembly according to claim 2, characterized in that the partition (22) is provided with a first vent hole (221) and a second vent hole; the first one-way communication member (23) opens or closes the first exhaust hole (221); the second one-way communication member (24) opens or closes the second exhaust hole.

4. A mixing cup assembly according to claim 1, wherein the first cavity (211) and the second cavity (212) each taper from the respective opening in the direction of the partition (22).

5. The mixing cup assembly of claim 1 or 4, wherein the volume of the first cavity (211) and the volume of the second cavity (212) are not equal.

6. A stirring cup assembly according to claim 5, characterized in that the partition (22) is integrally formed with the cover (21) or that the partition (22) can be detachably mounted in different positions of the cover (21) to correspondingly change the volume of the first cavity (211) and the volume of the second cavity (212).

7. The mixing cup assembly of claim 1, wherein the mixing cup assembly comprises a cup lid assembly (3), the cup (21) comprising opposite ends (215);

under the condition that the cup cover assembly (3) and the cup body assembly (1) are locked, one end (215) of the cover body (21) is abutted against the cup body (11), and the other end (215) of the cover body (21) is abutted against the cup cover assembly (3).

8. A mixing cup assembly according to claim 7, wherein a seal (4) is provided between one end (215) of the lid (21) and the cup (11) and between the other end (215) of the lid (21) and the cup lid assembly (3).

9. The stirring cup assembly according to claim 7, characterized in that the cup cover assembly (3) comprises a cover body (31) and a surrounding bone (32) arranged on the cover body (31); one end (215) of the cover body (21) is abutted against the cover body (31) and is covered by the surrounding bone (32);

And/or, the cup wall (111) of the cup body (11) is provided with a turbulence rib (1111) and a step (1112) connected with the turbulence rib (1111); both end parts (215) of the cover body (21) are provided with notches (2151);

Under the condition that the inner cover assembly (2) is placed forward, the turbulence ribs (1111) are clamped in the gaps (2151) in a one-to-one correspondence manner, and the end (215) positioned at one side of the first cavity (211) is abutted against the step (1112) so as to seal the first stirring cavity (213);

Under the condition that the inner cover assembly (2) is placed upside down, the turbulence ribs (1111) are clamped in the gaps (2151) in a one-to-one correspondence mode, and the end portions (215) located on one side of the second cavity (212) are abutted to the steps (1112) so as to seal the second stirring cavity (214).

10. A food processor comprising a main machine (20) and a blender cup assembly (10) according to any one of claims 1 to 9, wherein the main machine comprises a motor which drives the blade to rotate.