CN216364806U - Food processor - Google Patents

Abstract

The application provides a cooking machine. The cooking machine comprises a stirring cup and a cooking machine host machine used for bearing the stirring cup. The stirring cup comprises a cup body and a cup bottom wall assembly, wherein the cup body and/or the cup bottom wall assembly is provided with a mounting structure so as to detachably mount the cup bottom wall assembly at the bottom of the cup body, and the cup body and the cup bottom wall assembly enclose a processing space for containing food materials. The processor host computer includes heating element, bearing portion and heat-conducting element. The heating element is arranged in the inner space of the processor host. The bearing part is used for bearing the stirring cup and is provided with a bearing space for placing the bottom of the cup body. The heat conducting element is arranged at the bearing part and at least partially extends into the bearing space to be in contact with the stirring cup, and the heat conducting element is provided with an inner surface used for receiving heat generated by the heating element and an outer surface used for conducting the heat to the stirring cup.

Description

Food processor

Technical Field

The application relates to the field of household kitchen appliances, in particular to a food processor.

Background

A food processor for processing food materials in a home generally has a heating function and a whipping function. Correspondingly, the processor host is provided with a controller, a power conversion and distribution element, a motor and the like, and the stirring cup is provided with a heating element, an anti-overflow probe and other electric elements. However, after a period of use, the failure and repair caused by the heating elements on the mixing cup can increase significantly.

The inventors found that this is associated with frequent cleaning of the blender cup. After each time of stirring the food materials, the stirring cup is usually cleaned automatically or manually, food residues in the stirring cup are removed, and the food material processing space in the stirring cup is kept clean and sanitary. The heating element is arranged at the bottom of the stirring cup, and although a precise sealing structure is arranged between the heating element and the food material processing space, the risk of water passing of the heating element is increased continuously by vibration, frequent cleaning and the like in the stirring process.

Moreover, to achieve a thorough cleaning effect, the blade holder assembly is usually removed from the cup. However, the blending cup generally includes a cup body, a blade holder assembly and a cup holder, which are sequentially arranged from top to bottom, and the blade holder assembly is fixed at the bottom of the cup body by the cup holder and the cup body. This makes it necessary to disassemble the cup holder at the same time when disassembling the holder assembly, which is cumbersome.

Thus, there is a need to improve upon the above-mentioned drawbacks.

SUMMERY OF THE UTILITY MODEL

The application provides a cooking machine, it both can dismantle bottom of cup wall subassembly (for example, the blade holder subassembly) more conveniently, and then carries out stirring cup more thoroughly and clean, also can guarantee when cleaning not obviously increase the risk that relevant component broke down.

In order to achieve the above object, an embodiment of the present invention provides a food processor, which includes a stirring cup and a food processor host for carrying the stirring cup, wherein the stirring cup includes a cup body and a cup bottom wall assembly, the cup body and/or the cup bottom wall assembly is provided with a mounting structure for detachably mounting the cup bottom wall assembly at the bottom of the cup body, and the cup body and the cup bottom wall assembly enclose a processing space for accommodating food materials; the cooking machine host computer includes:

the heating element is arranged in the inner space of the processor host;

the bearing part is used for bearing the stirring cup and is provided with a bearing space for placing the bottom of the cup body;

the heat conducting element is arranged at the bearing part and at least partially extends into the bearing space so as to be in contact with the stirring cup, and the heat conducting element is provided with an inner surface used for receiving heat generated by the heating element and an outer surface used for conducting the heat to the stirring cup.

Because the cup bottom wall assembly is directly detachably mounted at the bottom of the cup body through the mounting structure, the cup bottom wall assembly can be directly detached from the cup body when the stirring cup needs to be thoroughly cleaned, and therefore, the cup bottom wall assembly can be quickly and thoroughly cleaned. Moreover, through setting up heating element in the inner space of cooking machine host computer to the heat conduction element that will correspond sets up in the bearing space department that can with stirring cup direct contact, makes heating element calorific capacity can high-efficiently transmit to the stirring cup, realizes the heating function to the stirring cup. Moreover, the arrangement can avoid arranging a heating element on the stirring cup, and reduce or even avoid the risk of damage or failure of the heating element.

Optionally, the heat conduction component includes along horizontal extension and is platelike heat conduction portion, the through-hole has been seted up to the middle zone of heat conduction portion, the inner space of cooking machine host computer is provided with the motor, the motor shaft of motor passes through the through-hole to stirring cup transmission power.

Through set up the through-hole of dodging motor power transmission on the heat conduction portion, can make things convenient for the heat conduction portion to link into a whole on the basis of guaranteeing power transmission.

Optionally, the heat conducting element further comprises a receiving portion, and the receiving portion comprises:

the side wall plate is in a hollow cylinder shape and extends vertically, and the upper end of the side wall plate is connected with the inner edge of the heat conducting part at the through hole;

the bottom wall plate extends along the transverse direction and is annular, the outer edge of the bottom wall plate is connected with the lower end of the side wall plate, and an avoidance hole is formed by the inner edge of the bottom wall plate in a surrounding mode;

the upper end of motor shaft passes through dodge the hole and get into the portion of holding, the upper end of motor shaft is connected with down the coupler.

Through the through-hole department at heat conduction portion sets up the lower coupler that holds the portion and be connected with motor shaft upper end, can make things convenient for the stirring cup to be connected with the power of cooking machine host computer in the aspect of power transmission on the one hand, on the other hand also can play the effect of sheltering from to the upper end of motor shaft.

Optionally, the heat conducting part vertically extends into the bearing space for a distance to contact the bottom of the stirring cup;

the heat conducting element further includes an annular shield portion extending in the vertical direction, and an upper end of the annular shield portion is connected to an outer edge of the heat conducting portion.

In the arrangement, the heat conducting part vertically extends into the bearing space for a certain distance, so that the heat conducting part is beneficial to stably keeping contact with the stirring cup; the annular shielding part connected with the outer edge of the heat conducting part can shield the lower part of the side part of the convex heat conducting part, and can prevent external foreign matters from entering the inner space of the processor host machine from the side part of the heat conducting element.

Optionally, the annular shield portion is disposed coaxially with the sidewall plate;

and/or the annular shield portion and the side wall plate are perpendicular to the heat conducting portion.

Optionally, the heat generating element is fixed to the inner surface of the heat conducting element;

and/or the heating element comprises a heating tube, an electric heating film or an electromagnetic coil.

The heating element is fixed on the heat conducting element, so that a separate structure is not required to be arranged to fix the heating element, the distance between the heating element and the heat conducting element can be shortened, and the heat conduction efficiency between the heating element and the heat conducting element is improved.

Optionally, the heat generating element includes an annular body having a gap.

Optionally, a first extending column and a second extending column are disposed at the notch of the heating element and are respectively used for being connected with the positive electrode and the negative electrode.

Optionally, the heat conducting element is provided with a hole, a temperature measuring probe is arranged in the hole, and the temperature measuring probe is located in the notch of the heating element.

Because the annular main body occupies most of the area of the inner surface of the heat conducting element, the first extending column body, the second extending column body and the temperature measuring probe are arranged at the notch of the heating element, so that the mutual influence between the heat conducting element and the temperature measuring probe can be avoided, and the inner surface area of the heat conducting element can be effectively utilized.

Optionally, the temperature measuring device further comprises a spring, one end of the spring is fixed, and the other end of the spring is connected to the temperature measuring probe, so that the temperature measuring probe can stretch up and down.

The temperature measuring probe is arranged in a floating mode, and is exposed out of the outer surface of the heat conducting element under the action of the spring when the stirring cup is not placed in the processor host; when the stirring cup is placed in the main machine of the food processor, the temperature measuring probe can be retracted under the action of the stirring cup and kept in contact with the stirring cup. Therefore, the contact between the temperature probe and the stirring cup can be kept, the temperature of the stirring cup can be accurately and reliably measured, and the temperature probe can be prevented from obstructing the direct contact between the stirring cup and the heat conducting element.

Optionally, the carrying part includes a bottom wall and a side wall, a lower end of the side wall is connected to an outer edge of the bottom wall, and the bottom wall and the side wall enclose the carrying space;

the height of the heat conducting element protruding upwards from the bottom wall is smaller than the height of the side wall.

The arrangement ensures that when the stirring cup is arranged on the bearing part, the side wall with higher protruding degree can bear most of load, and the heat conducting element can be prevented from being crushed by the stirring cup.

Optionally, the processor host computer includes:

the main body comprises the bearing part and a side shell, the side shell extends vertically and is annular, and the upper end part of the side shell is connected with the bearing part;

the base is located the below of main part, and with the main part equipment forms the shell of cooking machine host computer.

Optionally, the bottom wall assembly of the cup comprises a base body and a heat conducting plate, the base body is annular, a middle hole is formed in a middle area, the heat conducting plate is connected to the base body and covers the middle hole, the heat conducting plate is in contact with the heat conducting element through the middle hole, and the base body is mounted on the cup body.

In the above arrangement, the firm connection between the cup bottom wall assembly and the cup body is easily realized by utilizing the seat body with larger thickness and volume, and the heat conducting plate is arranged in the middle hole in the middle area of the seat body, so that the heat conducting plate can be exposed and arranged, and can be directly contacted with the heat conducting element of the food processor host machine.

Optionally, the cup bottom wall assembly is a tool apron assembly or a curing assembly; or the number of the cup bottom wall components is at least two, wherein one component is a tool apron component, and the other component is a curing component.

Because the function of different cup bottom wall subassemblies is different, therefore can realize the extension of cooking machine function through changing cup bottom wall subassembly.

Optionally, a columnar locking member is arranged on the heat conducting plate, a mounting hole penetrating through the base body is formed in the base body, and the mounting hole is matched with the columnar locking member of the heat conducting plate. The heat conducting plate and the seat body can be fixed through the arrangement.

Optionally, the heat conducting plate is of a single-layer structure or a multi-layer structure.

Optionally, a button and a fixed mount are arranged at the bottom of the cup body, the fixed mount is rotatably arranged and has an open state and a locked state, and the button is used for controlling the fixed mount to switch between the open state and the locked state;

in the locking state, the fixing frame locks the cup bottom wall component on the bottom of the cup body; in the open state, the cup bottom wall assembly is in a removable state.

Through the arrangement, the cup bottom wall assembly can be quickly disassembled.

Drawings

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

fig. 2 is a perspective view of the non-use state of the food processor of fig. 1, wherein the stirring cup is not placed on the host machine of the food processor;

FIG. 3 is a cross-sectional view of FIG. 1;

FIG. 4 is another cross-sectional view of FIG. 1;

FIG. 5 is an enlarged view of area A of FIG. 4;

fig. 6 to 11 are perspective exploded views of a part of the structure of fig. 1;

FIG. 12 is a schematic view of the mixing cup of the food processor of FIG. 1 during assembly and disassembly;

fig. 13 is a cross-sectional view of the food processor of fig. 1 in another use state.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent 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 certain aspects of the present application, as detailed in the appended 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 shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs. The use of the terms "a" or "an" and the like in the description and in the claims of this application do not denote a limitation of quantity, but rather denote the presence of at least one. The word "comprising" or "comprises", and the like, means that the element or item listed as preceding "comprising" or "includes" covers the element or item listed as following "comprising" or "includes" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "plurality" includes two, and is equivalent to at least two. 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 and all possible combinations of one or more of the associated listed items.

The embodiment of the application relates to a food processor. The food processor can be a wall breaking machine, a juice extractor, a soybean milk machine and other food processing appliances with heating function and whipping function.

As shown in fig. 1 to 4, the food processor 100 may include a food processor main body 2 and a stirring cup 1. In operation, the stirring cup 1 is placed above the processor host machine 2. After the processing is finished, the stirring cup 1 can be taken down from the main processor 2.

The lower end surface of the stirring cup 1 and the upper end surface of the processor host 2 can be provided with a mechanical matching piece and a conductive contact which are matched and connected with each other. The mechanical mating member may be a coupler. The conductive contacts may be conventional electrical connectors. After the stirring cup 1 is placed on the food processor main machine 2, the mechanical mating parts and the conductive contacts of the stirring cup 1 are correspondingly connected, so that the stirring cup 1 is mechanically and electrically connected with the food processor main machine 2, and the motor 52, the power distributor, the controller and the like which are arranged in the food processor main machine 2 can respectively provide power, power supply, signal control and other supports for the stirring cutter, the anti-overflow probe, the vacuum pumping pump and the like which are arranged in the stirring cup 1. The term whipping blade is to be understood broadly herein and may be a crushing blade, a grinding wheel, a wall breaking screw, etc.

The whole stirring cup 1 is supported above the processor main body 2. Of course, in other embodiments, the main machine of the food processor may be substantially C-shaped, and a half-open space is opened inside to accommodate the stirring cup. Except for the opening for the mixing cup to go in and out, three surfaces (including the upper surface, the lower surface and part of the side surface) of the mixing cup are shielded by the processor host. Correspondingly, the stirring cutter can be arranged at the upper part of the stirring cup; a motor shaft and coupler for transmitting power to the stirring cup can set up the upper portion position at cooking machine host computer to can stretch out and draw back from top to bottom. When the stirring cup needs to be placed, the motor shaft and the coupler which are positioned at the upper part of the processor host can be moved upwards; after the stirring cup is placed in the processor host, the motor shaft and the coupler can be driven to move downwards until the coupler is matched with the matching coupler on the stirring cup.

With reference to fig. 2 to 4 and fig. 5 to 8, the processor host 2 may include a heating element 22, a carrying portion 21 and a heat conducting element 23. The heating element 22 is disposed in the inner space of the processor host 2. The bearing part 21 is used for bearing the mixing cup 1 and is provided with a bearing space 215 for placing the bottom of the mixing cup 1. The heat conducting element 23 is arranged at the bearing part 21 and at least partially extends into the bearing space 215 to contact with the mixing cup 1. The heat conducting element 23 has an inner surface 2300 for receiving heat generated by the heating element 22 and an outer surface 2301 for conducting the heat to the mixing cup.

Through setting up heating element 22 in the inner space of cooking machine host computer 2 to set up the heat conduction element 23 that corresponds in bearing space 215 department that can with stirring cup 1 direct contact, make heating element 22 calorific capacity can high-efficiently transmit stirring cup 1, realize the heating function to stirring cup 1. Moreover, the arrangement can avoid arranging a heating element on the stirring cup 1, and reduce or even avoid the risk of damage or failure of the heating element. A number of test results show that: compare with the traditional cooking machine of heating element setting on the stirring cup, after using longer a period (for example, eight months), the fault frequency that leads to by heating element is less than traditional cooking machine far away in this application embodiment, and the number of times of breaking down is less than 5% of the number of times of breaking down of traditional cooking machine in the same cycle.

The heat conducting element 23 may include a heat conducting portion 230 extending in a transverse direction and having a plate shape, and a through hole 231 is formed in a middle region of the heat conducting portion 230, so that the heat conducting portion 230 has an annular shape as a whole. Correspondingly, the inner space of the processor host 2 is provided with a motor 28, and a motor shaft 281 of the motor 28 transmits power to the stirring cup 1 through the through hole 231.

Through set up the through-hole 231 of dodging motor power transmission on heat conduction portion 230, can make things convenient for heat conduction portion 230 to link into an entirety on the basis of guaranteeing power transmission. Of course, in other embodiments, the heat conducting portion 230 may be formed by splicing a plurality of independent heat conducting sheets, and thus, similar through holes for avoiding power transmission may not be required to be arranged in each heat conducting sheet. Moreover, the heat conducting part can also integrally extend vertically and is cylindrical, and the heat conducting part with the shape can be tightly attached to the bottom of the side wall of the stirring cup 1. Heat can also be transferred to the mixing cup 1 by contact with the side wall of the mixing cup 1. Of course, in the C-type processor as described above, it is not necessary to provide a through hole on the heat conduction portion to avoid the power transmission of the motor, because: the heat conducting part is connected with the bottom of the stirring cup in a matching mode, the power transmission of the motor is realized through the top of the stirring cup, and the stirring cup and the motor are far away from each other and cannot affect each other.

The heat conductive member 23 may further include an accommodating portion 232 in addition to the heat conductive portion 230. The accommodating portion 232 includes a side wall panel 233 and a bottom wall panel 234. The side wall plate 233 has a hollow cylindrical shape and extends vertically, and the upper end of the side wall plate 233 is connected to an inner edge 2302 of the heat conductive portion 230 at the through hole 231. The bottom wall plate 234 extends in the transverse direction and is annular, an outer edge 2341 of the bottom wall plate 234 is connected with the lower end of the side wall plate 233, and an inner edge 2340 of the bottom wall plate 234 surrounds a relief hole 235. The upper end of the motor shaft 281 enters the accommodating portion 232 through the avoiding hole 235, and the upper end of the motor shaft 281 is connected with a lower coupler 236.

Through set up the lower coupler 236 that holds 232 and be connected with motor shaft 281 upper end at the through-hole 231 department of heat conduction portion 230, can make things convenient for the power connection of stirring cup 1 with cooking machine host 2 in the aspect of power transmission on the one hand, on the other hand also can play the effect of sheltering from to the upper end of motor shaft 281.

Further, the heat conduction portion 230 may vertically extend into the bearing space 215 for a distance for better contact with the bottom of the mixing cup 1; correspondingly, the heat conducting element 23 may further include an annular shielding portion 237 extending vertically, an upper end of the annular shielding portion 237 is connected to the outer edge 2303 of the heat conducting portion 230, and a lower end of the annular shielding portion 237 may extend below the bearing portion 21 so as to be shielded by the bearing portion 21.

In the above arrangement, the heat conducting portion 230 vertically extends into the bearing space 215 for a distance, which is beneficial to stably keeping contact with the stirring cup 1; the annular shielding portion 237 connected to the outer edge of the heat conducting portion 230 can shield the lower side of the protruding side portion of the heat conducting portion 230, so as to prevent external foreign matters from entering the inner space of the food processor main body 2 from the side portion of the heat conducting element 23.

Further, the annular shield portion 237 may be provided coaxially with the side wall plate 233 of the accommodating portion 232. The annular shield portion 237 and the side wall plate 233 of the accommodating portion 232 may be perpendicular to the heat conductive portion 230. The annular shield portion 237, the heat conduction portion 230 and the side wall plate 233 of the accommodating portion 232 enclose a space. The heating element 22 may be disposed within the space.

The lower end of the annular shield portion 237 may extend laterally outward to form lateral flanges 241, 239, and the lateral flanges 241, 239 may extend below the bottom wall 210 of the carrier portion 21 to achieve the positioning of the annular shield portion 237. A hole 247 and a hole sleeve 244 corresponding to the hole 247 are further formed on the transverse flange 239, and screws or studs are sequentially screwed into the hole sleeve 244 and the hole 247, so that the annular shielding portion 237 and the bearing portion 21 can be fixed.

Further, the heat generating element 22 may be fixed to the inner surface 2300 of the heat conducting element 23. Fixing the heating element 22 to the heat conducting element 23 can either avoid providing a separate structure to fix the heating element 22 or shorten the interval therebetween to improve the heat conduction efficiency therebetween. In some embodiments, the heat generating element 22 may be secured to the heat conducting element 23 by welding. In some embodiments, the fixation of the two may be achieved by other means, such as a snap fit. In some embodiments, the heat generating element may be secured to the other element, with or without contacting the inner surface 2300 of the thermally conductive element 23. For non-contact situations, radiation can be used to transfer the heat generated by the heat generating element to the inner surface 2300 of the heat conducting element 23.

The heating element 22 may be a heating tube, an electric heating film or an electromagnetic coil, which generates heat energy by using electric energy. Of course, the heat generating element 22 may be an element that converts other forms of energy into heat energy, depending on the actual needs and application scenarios.

The heat generating element 22 may include a ring-shaped body 223 having a gap. The notch of the heat generating element 22 may be provided with a first extending column 224 and a second extending column 225, respectively for connecting with the positive and negative electrodes. The heat conducting element 23 is provided with a hole 238, a temperature measuring probe 24 for measuring the temperature at the hole 238 is arranged in the hole 238, and the temperature measuring probe 24 is positioned in the notch of the heating element 22.

Since the annular main body 223 occupies most of the area of the inner surface 2300 of the heat conducting element 23, disposing the first extension cylinder 224, the second extension cylinder 225 and the temperature probe 24 at the notch of the heat generating element 22 can avoid the mutual influence between the heat conducting element 23 and the temperature probe 24, and can also utilize the area of the inner surface 2300 of the heat conducting element 23 more efficiently.

The processor host machine 2 can also be provided with a spring 25, one end of the spring 25 is fixed, and the other end is connected with the temperature probe 24, so that the temperature probe 24 can stretch up and down. The temperature probe 24 is arranged in a floating mode, and when the stirring cup 1 is not placed in the processor host machine 2, the temperature probe 24 is exposed out of the outer surface 2301 of the heat conducting element 23 under the action of the spring 25; when the stirring cup 1 is placed in the processor host machine 2, the temperature measuring probe 24 can be retracted under the action of the stirring cup 1 and kept in contact with the stirring cup 1. Therefore, the contact between the temperature probe 24 and the stirring cup 1 can be kept, the temperature of the stirring cup 1 can be accurately and reliably measured, and the direct contact between the stirring cup 1 and the heat conducting element 23 can be prevented from being obstructed by the temperature probe 24.

The middle part of the temperature measuring probe 24 can be provided with an abutting part 243. The width of the abutting portion 243 is larger than the width of the hole 238, so that the abutting portion 243 is always positioned below the hole 238 and the heat conduction portion 230, thereby preventing the temperature probe 24 from being completely exposed from the hole 238 and being detached. A fixed pressing plate 26 is further provided, the pressing plate 26 is located below the spring 25, the lower end of the spring 25 abuts against and is fixed to the upper surface of the pressing plate 26, and the upper end of the spring 25 abuts against the lower surface of the abutting portion 243.

In the processor host 2, the carrying portion 21 may include a bottom wall 210 and a side wall 211, a lower end of the side wall 211 is connected to an outer edge 2101 of the bottom wall 210, and the bottom wall 210 and the side wall 211 enclose the carrying space 215. The height of the heat conducting element 23 protruding upward from the bottom wall 210 is smaller than the height of the side wall 211. The arrangement is such that, when the mixing cup 1 is placed on the bearing part 21, the side wall 211 with higher projection will bear most of the load, and the heat conducting element 23 will not be crushed by the mixing cup.

Further, the processor host 2 may further include a main body 20 and a base 31. The main body 20 includes the bearing part 21 and a side casing 27, the side casing 27 extends vertically and is annular, and an upper end of the side casing 27 is connected to the bearing part 21. The base 31 is located below the main body 20, and is assembled with the main body 20 to form the shell of the processor host. The motor 28 may be disposed within the base 31. The processor host 2 is also provided with a control panel 30 and a control circuit board 32.

In the embodiment shown in the figures, the carrying section 21 is formed integrally with the side casing 27. In other embodiments, the bearing portion 21 may be a separate component from the side casing 27, and the two may be assembled into a single unit. A vibration-proof pad 29 may be further disposed on the bottom wall 210 of the supporting portion 21, and the vibration-proof pad 29 is clamped between the supporting portion 21 and the mixing cup 1 to reduce the vibration of the mixing cup 1.

As shown in fig. 9-11, blender cup 1 may include a cup body 12, and a cup bottom wall assembly 13 mounted to the bottom of cup body 12. Cup 12 includes a cup sidewall 120 and a handle disposed on an outer surface of cup sidewall 120 for a user to hold. The cup bottom wall assembly 13 is detachably mounted on a cup body side wall 120 of the cup body 12 through a mounting structure (e.g., a button 121 and a fixing frame 122), and the cup body side wall 120 and the cup bottom wall assembly 13 enclose a processing space for accommodating food materials. The mounting structure is provided on the cup bottom wall assembly 13 and/or the cup sidewall 120.

Because the cup bottom wall assembly 13 is directly and detachably mounted at the bottom of the cup body 12 through the mounting structure, the cup bottom wall assembly 13 can be directly and detachably mounted on the cup body 12 when the stirring cup 1 needs to be thoroughly cleaned, so that quick and thorough cleaning can be realized.

Further, the cup bottom wall assembly 13 may include a seat body 131 and a heat conductive plate 133. The holder body 131 is ring-shaped, a middle hole 135 is formed in a middle region, the heat conducting plate 133 is connected to the holder body 131 and covers the middle hole 135, the heat conducting plate 133 contacts the heat conducting element 23 through the middle hole 135, and the holder body 131 is installed on the cup sidewall 120.

In the above arrangement, the base body 131 with a large thickness and a large volume is easy to realize the firm connection between the cup bottom wall assembly 13 and the cup body 12, and the heat conducting plate 133 is disposed in the middle hole 135 in the middle region of the base body 131 to realize the exposed arrangement of the heat conducting plate 133, so that the heat conducting plate can directly contact the heat conducting element 23 of the processor main machine 2.

A tool apron sealing ring 132 can be arranged between the heat conducting plate 133 and the seat body 131 or/and between the seat body 131 and the cup body side wall 120, so that the sealing performance of the stirring cup 1 is improved.

The cup bottom wall assembly 13 may be a blade holder assembly 14 or a curing assembly 15. The blade holder assembly 14 or the curing assembly 15 are replaceable elements. Wherein the cutter assembly 14 is further provided with a beating cutter 141, the beating cutter 141 can be fixed on the heat conductive plate 133 by a lock nut 142. The curing assembly 15 only has a heating or heat conducting function. When food materials such as fruit juice, soybean milk and the like which need to be stirred are prepared, the tool apron assembly 14 can be arranged at the bottom of the side wall 120 of the cup body; in the preparation of steamed eggs, mung bean porridge, etc., which require only heating, the holder assembly 14 may be removed and the health preserving assembly 15 may be mounted to the bottom of the cup body side wall 120.

Further, the heat conducting plate 133 is provided with a column locking member 1330, the seat body 131 is provided with a mounting hole 1310 penetrating through the seat body 131, and the mounting hole 1310 is adapted to the column locking member 1330 of the heat conducting plate 133. The above arrangement can achieve the fixation between the heat conducting plate 133 and the seat body 131.

The heat conductive plate 133 has a single-layer structure or a multi-layer structure. In the embodiment shown in the drawings, the heat conductive plate 133 has a double-layer structure.

The mixing cup 1 may further comprise a cup cover 11 and a venting cover 10. The cup lid 11 is arranged at an opening above the cup body 12. A feeding hole is formed in the middle area of the cup cover 11. An exhaust cover 10 is installed at the charging hole. A steam channel is arranged in the exhaust cover 10 and can be used for exhausting steam generated during heating; moreover, the width of the steam channel is smaller and obviously smaller than the size of the feeding hole, so that the noise generated by whipping can be obviously reduced.

As shown in fig. 12, a button 121 and a fixing frame 122 may be disposed at the bottom of the cup sidewall 120, the fixing frame 122 may be rotatably disposed and has an open state and a locked state, and the button 121 is used to control the fixing frame 122 to switch between the open state and the locked state.

In the locked state, the fixing frame 122 locks the cup bottom wall assembly 13 to the bottom of the cup side wall 120; in the open state, the cup bottom wall assembly 13 is in a removable state.

Through the arrangement, the cup bottom wall assembly 13 can be quickly disassembled; quick replacement of the tool holder assembly 14 and the curing assembly 15 is also possible.

Fig. 13 shows a usage state in which the health preserving assembly 15 is mounted in the mixing cup 1 and the food processor 100. The health preserving component 15 can be used for preparing nutritional foods such as mung bean porridge, egg custard and the like.

Of course, in other embodiments, the mounting structure for removably mounting the cup 12 to the cup bottom wall assembly 13 may be other than the structure between the button 121 and the holder 122, such as: the interference mechanism of lug and lug, the matching structure of lug and recess, the buckle structure of fixture block and draw-in groove, the screw thread locking structure of internal thread and external screw thread.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the scope of protection of the present application.

Claims (14)

1. The food processor is characterized by comprising a stirring cup (1) and a food processor host (2) used for bearing the stirring cup (1), wherein the stirring cup (1) comprises a cup body (12) and a cup bottom wall component (13), the cup body (12) and/or the cup bottom wall component (13) are/is provided with a mounting structure so as to detachably mount the cup bottom wall component (13) at the bottom of the cup body (12), and the cup body (12) and the cup bottom wall component (13) enclose a processing space for containing food materials;

wherein, the cooking host computer includes:

a heating element (22) disposed in the internal space of the processor main body (2);

a bearing part (21) for bearing the mixing cup (1) and provided with a bearing space (215) for placing the bottom of the cup body (12) therein;

a heat conducting element (23) arranged at the bearing part (21) and at least partially extending into the bearing space (215) to contact with the mixing cup (1), wherein the heat conducting element (23) is provided with an inner surface (2300) for receiving heat generated by the heating element (22) and an outer surface (2301) for conducting the heat to the mixing cup.

2. The food processor as claimed in claim 1, wherein the heat conducting element (23) comprises a heat conducting portion (230) extending in a transverse direction and having a plate shape, a through hole (231) is formed in a middle area of the heat conducting portion (230), a motor (28) is disposed in an inner space of the food processor main body (2), and a motor shaft (281) of the motor transmits power to the stirring cup (1) through the through hole (231).

3. The food processor of claim 2, wherein the heat conducting element (23) further comprises a receiving portion (232), the receiving portion (232) comprising:

the side wall plate (233) is in a hollow cylinder shape and extends vertically, and the upper end of the side wall plate (233) is connected with the inner edge of the heat conducting part (230) at the through hole (231);

the bottom wall plate (234) extends along the transverse direction and is annular, the outer edge of the bottom wall plate (234) is connected with the lower end of the side wall plate (233), and the inner edge of the bottom wall plate (234) is surrounded to form an avoiding hole (235);

the upper end of motor shaft (281) passes through dodge hole (235) and gets into accommodate portion (232), the upper end of motor shaft (281) is connected with down coupler (236).

4. The food processor of claim 3, wherein the heat conducting portion (230) vertically extends into the carrying space (215) for a distance for contacting the bottom of the mixing cup (1);

the heat conductive member (23) further includes an annular shield portion (237) extending in the vertical direction, and an upper end of the annular shield portion (237) is connected to an outer edge of the heat conductive portion (230).

5. The food processor of claim 4, wherein the annular shield portion (237) is disposed coaxially with the sidewall plate (233);

and/or the annular shield portion (237) and the side wall plate (233) are perpendicular to the heat conductive portion (230).

6. The food processor of claim 1, wherein the heating element (22) is fixed to the inner surface (2300) of the heat conducting element (23);

and/or the heating element (22) comprises a heating tube, an electrothermal film or an electromagnetic coil.

7. The food processor of claim 1, wherein the heat generating component (22) comprises an annular body (223) having a notch;

a first extending column (224) and a second extending column (225) are arranged at the notch of the heating element (22) and are respectively used for being connected with the positive electrode and the negative electrode;

the heat conducting element (23) is provided with a hole (238), a temperature measuring probe (24) is arranged in the hole (238), and the temperature measuring probe (24) is positioned in the notch of the heating element (22).

8. The food processor as claimed in claim 7, further comprising a spring (25), wherein one end of the spring (25) is fixed, and the other end is connected to the temperature probe (24), so that the temperature probe (24) can be extended and retracted up and down.

9. The food processor of claim 1, wherein the carrying part (21) comprises a bottom wall (210) and a side wall (211), the lower end of the side wall (211) is connected with the outer edge of the bottom wall (210), and the bottom wall (210) and the side wall (211) enclose the carrying space (215);

the heat-conducting element (23) protrudes upwards from the bottom wall (210) to a height which is less than the height of the side wall (211).

10. The food processor of claim 1, wherein the host machine comprises:

a main body (20) including the bearing portion (21) and a side case (27), the side case (27) extending vertically and being annular, an upper end portion of the side case (27) being connected to the bearing portion (21);

the base (31) is positioned below the main body (20) and assembled with the main body (20) to form the shell of the processor host.

11. The food processor of claim 1, wherein the cup bottom wall assembly (13) comprises a seat body (131) and a heat conducting plate (133), the seat body (131) is ring-shaped, a middle area is formed with a middle hole (135), the heat conducting plate (133) is connected to the seat body (131) and covers the middle hole (135), the heat conducting plate (133) is contacted with the heat conducting element (23) through the middle hole (135), and the seat body (131) is installed on the cup body (12).

12. The food processor of claim 11, wherein the cup bottom wall assembly (13) is a knife holder assembly (14) or a curing assembly (15); alternatively, the first and second electrodes may be,

the number of the cup bottom wall components (13) is at least two, wherein one is a tool apron component (14) and the other is a curing component (15).

13. The food processor of claim 11, wherein the heat conducting plate (133) is provided with a column-shaped locking member (1330), the seat body (131) is provided with a mounting hole (1310) penetrating through the seat body (131), and the mounting hole (1310) is matched with the column-shaped locking member (1330) of the heat conducting plate (133).

14. The food processor of claim 11, wherein the mounting structure comprises a button (121) and a holder (122) arranged at the bottom of the cup body (12), the holder (122) is rotatably arranged and has an open state and a locked state, and the button (121) is used for controlling the holder (122) to switch between the open state and the locked state;

in the locking state, the fixing frame (122) locks the cup bottom wall assembly (13) at the bottom of the cup body (12); in the open state, the cup bottom wall assembly (13) is in a detachable state.

Images