A detachable and washable soy milk maker

CN224420860UActive Publication Date: 2026-06-30GUANGDONG CHANGSHENG ELECTRIC CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG CHANGSHENG ELECTRIC CO LTD
Filing Date
2025-07-16
Publication Date
2026-06-30

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Abstract

This utility model discloses a detachable and washable soymilk maker, including a base, a processing chamber, a heating element, and a driving element. The heating element is disposed in the processing chamber; the driving element is disposed at the bottom end of the processing chamber and has a driving shaft; the soymilk processing assembly includes a soymilk container and a blade mechanism, the soymilk container being detachably installed in the processing chamber; the blade mechanism includes a blade shaft and blades, the blades being disposed on the blade shaft, the blade shaft being rotatably installed in the soymilk container, and the blade shaft being detachably connected to the driving shaft. The detachable and washable soymilk maker of this utility model allows the soymilk container to be separated from the processing chamber of the base for easy cleaning; and the heating element is disposed in the base, so disassembling and cleaning the soymilk container does not affect the structure of the heating element.
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Description

Technical Field

[0001] This utility model relates to the field of soymilk maker technology, and in particular to a detachable and washable soymilk maker. Background Technology

[0002] A typical soy milk maker has internal stirring blades. After adding an appropriate amount of water and turning on the power, the stirring blades mix the water and soybeans in the soy milk container to produce soy milk. Additionally, a heating element can be installed inside the soy milk maker to heat the soy milk liquid in the container. Continuous stirring and heating thoroughly grind the soybeans, initially boil the soy milk, and then continue heating during the final cooking stage to ensure the soy milk is fully cooked and completely emulsified.

[0003] However, existing soy milk makers typically have the soy milk container and base molded as a single piece, making it inconvenient to clean by simply pouring water into the container. Furthermore, soy pulp easily accumulates on the mixing blades, and if the soy milk container cannot be removed during cleaning, the mixing blades cannot be thoroughly cleaned. Utility Model Content

[0004] In order to overcome at least one of the defects of the prior art, the present invention provides a detachable and washable soymilk maker, wherein the soymilk container can be separated from the processing chamber of the machine base for easy cleaning; and the heating element is located on the machine base, so the structure of the heating element is not affected when the soymilk container is disassembled and cleaned.

[0005] The technical solution adopted by this utility model to solve its problem is:

[0006] A detachable and washable soy milk maker includes,

[0007] A machine base is provided with a processing cavity, a heating element, and a driving element. The heating element is disposed in the processing cavity. The driving element is disposed at the bottom end of the processing cavity and is provided with a driving shaft.

[0008] A soy milk processing assembly includes a soy milk container and a blade mechanism. The soy milk container is detachably installed in the processing chamber. The blade mechanism includes a cutter shaft and blades. The blades are disposed on the cutter shaft, which is rotatably installed in the soy milk container. The cutter shaft is detachably connected to the drive shaft.

[0009] As an optional implementation, the detachable and washable soymilk maker also includes a linkage switch assembly.

[0010] The linkage switch assembly includes a linkage rod, a first elastic component, and a detection switch. The linkage rod is installed on the outer wall of the soy milk container and can move up and down. The linkage rod has a first end and a second end. One end of the first elastic component is connected to the linkage rod, and the other end of the first elastic component is connected to the outer wall of the soy milk container. The first elastic component is used to provide an elastic stress that drives the first end upward. The detection switch is installed inside the processing cavity. The first end is used to drive the second end downward when subjected to external force, so as to press the detection switch and send an electrical signal. The driving component is used to receive the electrical signal.

[0011] As an optional implementation, the outer wall of the soy milk bucket is provided with a mounting shell, and the mounting shell is provided with a mounting cavity. The linkage rod and the first elastic component are both installed in the mounting cavity. The top end of the mounting cavity is provided with a first through-hole, and the bottom end of the mounting cavity is provided with a second through-hole. The first end is provided with a corresponding first through-hole, and the second end is provided with a corresponding second through-hole.

[0012] As an optional implementation, the side of the base is provided with a positioning notch, which communicates with the processing cavity; the mounting shell is used to pass through the positioning notch after the soy milk bucket is installed in the processing cavity.

[0013] As an optional implementation, the mounting housing is provided with a handheld component that extends out of the processing cavity through the positioning notch.

[0014] As an optional implementation, the soy milk processing assembly further includes a cover plate, on which a pressing member is provided. The pressing member is used to press the first end after the cover plate is sealed to the soy milk container.

[0015] As an optional implementation, the linkage switch assembly further includes a touch lever and a second elastic component. The touch lever is connected to the base via the second elastic component, which provides an elastic stress that drives the touch lever upward. The touch lever is pressed down by the second end and moves downward to touch the detection switch.

[0016] As an optional implementation, the heating element includes a heating plate, which is sealed to the bottom wall of the processing cavity. The heating plate protrudes upward in the middle to form a positioning boss. A first through hole is provided in the middle of the positioning boss. The bottom end of the soy milk bucket is provided with a positioning recess that matches the positioning boss. A second through hole is provided in the middle of the positioning recess.

[0017] The driving component is located below the positioning boss, and the driving shaft extends into the processing cavity through the first through hole; a heat insulation cover is provided around the driving shaft.

[0018] As an optional implementation, the inner wall of the processing cavity is provided with a plurality of positioning spring pins, which are distributed at intervals in the circumferential direction of the processing cavity.

[0019] As an optional implementation, the bottom of the soy milk container is made of stainless steel.

[0020] In summary, this utility model has the following technical effects:

[0021] After the soy milk beverage is made, the soy milk container can be removed from the processing chamber. The blade shaft inside the soy milk container can be detached from the drive shaft of the processing chamber. The soy milk container can be cleaned separately after being removed from the base. Since the soy milk container has a blade mechanism inside, the blade mechanism can be cleaned simultaneously during the cleaning process, making cleaning convenient. The heating element and drive mechanism, among other electrical components, are all assembled inside the base. Therefore, when cleaning the soy milk container and blade mechanism, the cleaning water will not affect the electrical components inside the base, making electrical use safer. Attached Figure Description

[0022] To more clearly illustrate the technical solutions in the embodiments of this utility model, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0023] Figure 1 This is an exploded view of the soy milk maker of this utility model;

[0024] Figure 2 This is a cross-sectional view of the soy milk maker of this utility model;

[0025] Figure 3 This is a schematic diagram of the structure of the soy milk maker of this utility model;

[0026] Figure 4 This is a cross-sectional view of the soy milk bucket and blade mechanism of this utility model;

[0027] Figure 5 This is a schematic diagram of the structure of the soy milk bucket and blade mechanism of this utility model;

[0028] Figure 6 This is a schematic diagram of the soybean milk bucket and blade mechanism from another perspective of the present invention.

[0029] Figure 7 This is a schematic diagram of the structure of the cover plate of this utility model;

[0030] Figure 8This is a schematic diagram of the structure of the driving component, heating plate, second touch lever, and detection switch of this utility model.

[0031] The meanings of the reference numerals in the attached drawings are as follows: 10, machine base; 11, processing cavity; 12, positioning notch; 13, positioning spring pin; 14, heating plate; 141, positioning boss; 15, driving component; 20, soy milk bucket; 21, mounting shell; 211, first through-hole; 212, second through-hole; 213, mounting cavity; 22, hand-held component; 23, cover plate; 231, top pressing component; 24, blade mechanism; 241, blade shaft; 242, blade; 25, positioning recess; 31, linkage rod; 311, first end; 312, second end; 32, detection switch; 33, touch control rod. Detailed Implementation

[0032] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0033] In this invention, the terms "upper," "lower," "left," "right," "front," "rear," "top," "bottom," "inner," "outer," "middle," "vertical," "horizontal," "lateral," and "longitudinal" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. These terms are primarily for the purpose of better describing this invention and its embodiments, and are not intended to limit the indicated device, element, or component to having a specific orientation, or to be constructed and operated in a specific orientation.

[0034] Furthermore, in addition to indicating direction or positional relationship, some of the aforementioned terms may also have other meanings. For example, the term "above" may also be used in some cases to indicate a certain dependency or connection relationship. Those skilled in the art can understand the specific meaning of these terms in this utility model according to the specific circumstances.

[0035] Furthermore, the terms "installation," "setup," "equipped with," "connection," and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral structure; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium, or an internal connection between two devices, components, or parts. Those skilled in the art can understand the specific meaning of these terms in this utility model based on the specific circumstances.

[0036] Furthermore, the terms "first," "second," etc., are primarily used to distinguish different devices, components, or parts (which may be the same or different in specific type and construction), and are not intended to indicate or imply the relative importance or quantity of the indicated devices, components, or parts. Unless otherwise stated, "a plurality of" means two or more.

[0037] The technical solution of this utility model will be further described below with reference to the embodiments and accompanying drawings.

[0038] See Figures 1-8 This utility model discloses a detachable and washable soymilk maker, including a base 10 and a soymilk processing assembly. The base 10 is provided with a processing chamber 11, a heating element, and a driving element 15. The heating element is installed in the processing chamber 11 and can heat the processing chamber 11. The heating element can be located on the bottom wall or side wall of the processing chamber 11, as long as it can heat the processing chamber 11. The driving element 15 is located at the bottom end of the processing chamber 11 and is provided with a drive shaft.

[0039] The soy milk processing assembly includes a soy milk container 20 and a blade mechanism 24. The soy milk container 20 is detachably installed in the processing chamber 11. The blade mechanism 24 includes a blade shaft 241 and a blade 242. The blade 242 is disposed on the blade shaft 241. The blade shaft 241 is rotatably installed on the soy milk container 20. The blade shaft 241 is detachably connected to the drive shaft.

[0040] Based on the above structure, when using the detachable and washable soymilk maker of this utility model to make soymilk, the soymilk container 20 is assembled into the processing chamber 11, and the blade shaft 241 inside the soymilk container 20 can be connected to the drive shaft at the bottom of the processing chamber 11. Soybeans are placed into the soymilk container 20 and water is poured in. The drive unit 15 is activated, and the drive shaft of the drive unit 15 drives the blade shaft 241 to rotate. The blades 242 on the blade shaft 241 can then cut and crush the soybeans in the soymilk container 20 to form soymilk liquid. Of course, after the soymilk liquid is formed, the heating element inside the processing chamber 11 can be activated to heat the soymilk liquid, making hot soymilk and improving the taste of the soymilk beverage.

[0041] After the soy milk beverage is made, the soy milk container 20 can be removed from the processing chamber 11. The blade shaft 241 inside the soy milk container 20 can be detached from the drive shaft of the processing chamber 11. The soy milk container 20 can be cleaned separately after being detached from the base 10. Since the blade mechanism 24 is installed inside the soy milk container 20, it can be cleaned simultaneously during the cleaning process, making cleaning convenient. The heating element and drive element 15, among other electrical components, are all assembled inside the base 10. Therefore, when cleaning the soy milk container 20 and the blade mechanism 24, the cleaning water will not affect the electrical components inside the base 10, making electrical use safer.

[0042] Of course, in some related implementation structures, the end of the cutter shaft 241 can protrude through the bottom wall of the soy milk container 20, and a sealing sleeve or sealing ring or other sealing structure can be provided at the through-hole connection position between the cutter shaft 241 and the soy milk container 20 to prevent the soy milk liquid or water in the soy milk container 20 from overflowing. The end of the cutter shaft 241 can be provided with a first connecting structure, and the end of the drive shaft can be provided with a second connecting structure. The first connecting structure and the second connecting structure can be detachably connected by insert fitting, or they can be disassembled and assembled by spline insert fitting, which is convenient for disassembly and assembly.

[0043] As an optional implementation, the detachable and washable soymilk maker also includes a linkage switch assembly. Specifically, the linkage switch assembly includes a linkage rod 31, a first elastic component, and a detection switch 32. The linkage rod 31 is installed on the outer wall of the soymilk container 20 and can move up and down. Since the linkage rod 31 is located on the outer wall of the soymilk container 20, the movement of the linkage rod 31 is outside the soymilk container 20 and will not interfere with the soymilk liquid or cleaning water received inside.

[0044] The linkage rod 31 has a first end 311 and a second end 312. One end of the first elastic member is connected to the linkage rod 31, and the other end of the first elastic member is connected to the outer wall of the soy milk container 20. The first elastic member is used to provide an elastic stress that drives the first end 311 upward. The detection switch 32 is installed in the processing cavity 11. The first end 311 is used to drive the second end 312 downward when subjected to external force, so as to press the detection switch 32 and send an electrical signal. The driving member 15 is used to receive the electrical signal.

[0045] Based on this structure, since a detection switch 32 is set in the processing chamber 11, when the soybean milk bucket 20 is assembled, after the processing chamber 11 is completed, the linkage rod 31 on the soybean milk bucket 20 can be positioned above the detection switch 32. After the soybean milk bucket 20 is assembled, and the blade shaft 241 of the soybean milk bucket 20 is in place with the drive shaft of the drive component 15, the first end 311 of the linkage rod 31 outside the soybean milk bucket 20 can be pressed. The first end 311 of the linkage rod 31 will be forced to drive the second end 312 of the linkage rod 31 to move downward and press the detection switch 32. The detection switch 32 will then be touched and send an electrical signal. The drive component 15 can then receive the electrical signal and start. That is to say, the detection switch 32 is only activated by the linkage rod 31 after the soybean milk bucket 20 is in place, and the blade mechanism 24 can rotate under the drive of the drive component 15. This makes it safer to use and prevents the drive component 15 from being accidentally activated if the soybean milk bucket 20 is not in place.

[0046] More specifically, to facilitate the assembly of the linkage switch assembly, a mounting shell 21 can be provided on the outer wall of the soy milk container 20, and a mounting cavity 213 can be provided inside the mounting shell 21. The mounting shell 21 can be assembled to the outer wall of the soy milk container 20 by means of screws or bolts, etc., and the linkage rod 31 and the first elastic component are both installed in the mounting cavity 213. A first through-hole 211 is provided at the top of the mounting cavity 213; a second through-hole 212 is provided at the bottom of the mounting cavity 213. The first end 311 is corresponding to the first through-hole 211, and the second end 312 is corresponding to the first through-hole 212. The two through-holes 212 are correspondingly arranged, meaning that the linkage rod 31 can be installed in the mounting cavity 213 of the mounting shell 21 through the first elastic component. Under the elastic stress of the first elastic component, the first end 311 of the linkage rod 31 can maintain an upward movement tendency. The first end 311 can be inserted into the first through-hole 211, specifically it can be inserted through the first through-hole 211 or it can be located exactly in the first through-hole 211. When pressing the first end 311, force is applied to the first end 311 through the first through-hole 211, or force is applied directly to the first end 311 from the outside. After being subjected to force, the linkage rod 31 drives the second end 312 to move downward, and the second end 312 can then be inserted through the second through-hole 212 to press the detection switch 32. In this way, the movement of the linkage rod 31 and the first elastic component are both within the mounting shell 21, reducing interference from external structures.

[0047] Of course, when cleaning the soy milk bucket 20, the mounting shell 21 can also be placed around the linkage rod 31 and the first elastic component, thus reducing the impact of cleaning water on the linkage rod 31 and the first elastic component.

[0048] As an optional implementation, a positioning notch 12 can also be provided on the side of the base 10. The positioning notch 12 communicates with the processing cavity 11. Since the mounting shell 21 protrudes from the outer wall of the soy milk bucket 20 after it is installed on the outer wall of the soy milk bucket 20, the processing cavity 11 needs a certain space to accommodate the mounting shell 21 on the soy milk bucket 20 after the soy milk bucket 20 is assembled. If the inner diameter of the processing cavity 11 is directly increased to match the outer diameter of the mounting shell 21 of the soy milk bucket 20, then the part of the soy milk bucket 20 without the mounting shell 21 may form a large gap with the inner wall of the processing cavity 11. In this way, the soy milk bucket 20 is prone to shaking when performing soy milk processing inside.

[0049] Therefore, a positioning notch 12 is provided on the side of the base 10. After the soy milk bucket 20 is installed in the processing cavity 11, it passes through the positioning notch 12. The positioning notch 12 avoids the mounting shell 21 on the soy milk bucket 20, so there is no need to increase the inner diameter of the processing cavity 11. This allows the soy milk bucket 20 to fit and abut against the inner wall of the processing cavity 11, making the structure of the soy milk bucket 20 more stable after assembly. At the same time, the through-fitting of the positioning notch 12 and the mounting shell 21 can also limit the shaking of the soy milk bucket 20.

[0050] More specifically, the housing 21 can also be equipped with a hand-held component 22, such as a handle, grip, or carrying handle. The hand-held component 22 extends out of the processing cavity 11 through the positioning notch 12. The user can easily pick up and put down the soy milk bucket 20 by operating the hand-held component 22.

[0051] As an optional implementation, the soy milk processing assembly also includes a cover plate 23, on which a pressing member 231 is provided. The pressing member 231 is used to press the first end 311 after the cover plate 23 is sealed to the soy milk container 20. Based on this structure, after the soy milk container 20 is assembled into the processing chamber 11, the cover plate 23 can be sealed to the top of the soy milk container 20, and the pressing member 231 on the cover plate 23 can correspond to the first end 311 of the linkage rod 31 for sealing. In this way, after the cover plate 23 is sealed in place, The pressing member 231 on the cover plate 23 can press the first end 311 of the linkage rod 31. When the first end 311 of the linkage rod 31 is subjected to force, it can drive the second end 312 of the linkage rod 31 to move downward and press the detection switch 32. The detection switch 32 can be touched and send an electrical signal. The driving member 15 can then receive the electrical signal and start. In this way, the driving member 15 is started by the sealing action of the cover plate 23 of the soy milk bucket 20, that is, soy milk is made in the state of the soy milk bucket 20 being in a closed state.

[0052] As an optional implementation, the aforementioned linkage switch assembly further includes a touch lever 33 and a second elastic component. The touch lever 33 is connected to the base 10 via the second elastic component. The second elastic component provides an elastic stress that drives the touch lever 33 upward. The touch lever 33 can be pressed down by the second end 312 and move downward to touch the detection switch 32. Specifically, during the pressing action, the second end 312 of the linkage rod 31 moves downward to press the touch lever 33, causing the touch lever 33 to move downward to touch the detection switch 32. In this way, the touch lever 33 can compensate for the downward movement of the second end 312 of the linkage rod 31. The overall length of the linkage rod 31 does not need to be too long, nor will it protrude from the bottom of the soy milk container 20.

[0053] It should be noted that in some implementations, the detection switch 32 can be selected as a spring switch or a photoelectric switch, etc.

[0054] As an optional implementation, the heating element includes a heating plate 14, which is sealed to the bottom wall of the processing cavity 11. This allows the heating plate 14 to form a larger heating surface on the bottom wall of the processing cavity 11, resulting in higher heating efficiency for the soy milk container 20.

[0055] Specifically, a positioning boss 141 protrudes upward from the center of the heating plate 14, and a first through hole is provided in the center of the positioning boss 141; the bottom end of the soy milk container 20 is provided with a positioning recess 25 that matches the positioning boss 141, and a second through hole is provided in the center of the positioning recess 25; after the soy milk container 20 is assembled into the processing chamber 11, the bottom wall of the soy milk container 20 can be positioned and assembled with the positioning boss 141 of the heating plate 14 through the positioning recess 25, which can reduce the shaking that occurs when processing soy milk in the soy milk container 20. At the same time, the assembly method of the positioning boss 141 and the positioning recess 25 can increase the contact surface between the heating plate 14 and the soy milk container 20, so the heat transfer efficiency is higher and the heating speed is faster.

[0056] Furthermore, the aforementioned drive component 15 is located below the positioning boss 141, and the drive shaft extends into the processing cavity 11 through the first through hole. Thus, after the soy milk container 20 is assembled into the processing cavity 11, the drive shaft can be detachably connected to the cutter shaft 241 extending through the second through hole via the first through hole. To prevent the drive component 15 from being affected by the heat from the heating plate 14, a heat insulation cover can be provided around the drive shaft. This heat insulation cover surrounds the outer periphery of the drive component 15 and the drive shaft, reducing overheating of the drive component 15 during operation of the heating plate 14 and improving the service life of the drive component 15.

[0057] Of course, the heating plate mentioned above can also be implemented using other heating structures such as heating coils or heating resistors.

[0058] As an optional implementation, multiple positioning spring pins 13 can also be provided on the inner wall of the processing cavity 11. The multiple positioning spring pins 13 are distributed at intervals in the circumferential direction of the processing cavity 11. After the soy milk bucket 20 is assembled into the processing cavity 11, the multiple positioning spring pins 13 can contact the outer wall of the soy milk bucket 20 for positioning and abutment, so that the assembly structure of the soy milk bucket 20 on the inner wall of the processing cavity 11 is more stable.

[0059] As an optional implementation, the bottom of the soy milk container 20 is made of stainless steel. After the soy milk container 20 is assembled into the processing chamber 11, it comes into contact with the heating plate at the bottom. The stainless steel soy milk container 20 can conduct heat, so that the heat generated by the heating plate can be quickly transferred to the inside of the soy milk container 20, thus making the heating efficiency higher.

[0060] Of course, other heat-conducting structures, such as heat-conducting silicone or heat-conducting aluminum sheets, can be installed on the bottom or side walls of the soy milk container. In this way, the heat can be quickly transferred to the soy milk container through the contact between the heat-conducting structure and the heating element, thereby improving the heating efficiency.

[0061] The technical means disclosed in this utility model are not limited to those disclosed in the above embodiments, but also include technical solutions composed of any combination of the above technical features. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of this utility model, and these improvements and modifications are also considered within the scope of protection of this utility model.

Claims

1. A detachable and washable soymilk maker characterized in that, include, A machine base, wherein the machine base is provided with a processing cavity, a heating element and a driving element, and the heating element is disposed in the processing cavity; The driving component is located at the bottom end of the processing cavity, and the driving component is provided with a driving shaft; A soy milk processing assembly includes a soy milk container and a blade mechanism. The soy milk container is detachably installed in the processing chamber. The blade mechanism includes a cutter shaft and blades. The blades are disposed on the cutter shaft, which is rotatably installed in the soy milk container. The cutter shaft is detachably connected to the drive shaft.

2. The instant soy milk maker according to claim 1, wherein The detachable and washable soymilk maker also includes a linkage switch assembly. The linkage switch assembly includes a linkage rod, a first elastic component, and a detection switch. The linkage rod is installed on the outer wall of the soy milk container and can move up and down. The linkage rod has a first end and a second end. One end of the first elastic component is connected to the linkage rod, and the other end of the first elastic component is connected to the outer wall of the soy milk container. The first elastic component is used to provide an elastic stress that drives the first end upward. The detection switch is installed inside the processing cavity. The first end is used to drive the second end downward when subjected to external force, so as to press the detection switch and send an electrical signal. The driving component is used to receive the electrical signal.

3. The detachable and washable soymilk maker according to claim 2, characterized in that, The outer wall of the soy milk bucket is provided with an installation shell, and an installation cavity is provided inside the installation shell. The linkage rod and the first elastic component are both installed in the installation cavity. A first through-hole is provided at the top of the installation cavity. A second through-hole is provided at the bottom of the installation cavity. The first end is provided corresponding to the first through-hole, and the second end is provided corresponding to the second through-hole.

4. The detachable and washable soymilk maker according to claim 3, characterized in that, The side of the base is provided with a positioning notch, which communicates with the processing cavity; the mounting shell is used to pass through the positioning notch after the soy milk bucket is installed in the processing cavity.

5. The detachable and washable soymilk maker according to claim 4, characterized in that, The mounting housing is provided with a handheld component, which extends out of the processing cavity through the positioning notch.

6. The detachable and washable soymilk maker according to claim 2, characterized in that, The soy milk processing assembly also includes a cover plate, on which a pressing member is provided. The pressing member is used to press the first end after the cover plate is sealed to the soy milk container.

7. The detachable and washable soymilk maker according to claim 2, characterized in that, The linkage switch assembly further includes a touch lever and a second elastic component. The touch lever is connected to the base via the second elastic component, which provides an elastic stress that drives the touch lever upward. The touch lever is pressed down by the second end and moves downward to touch the detection switch.

8. The detachable and washable soymilk maker according to any one of claims 1-7, characterized in that, The heating element includes a heating plate, which is sealed to the bottom wall of the processing cavity. The heating plate protrudes upward in the middle to form a positioning boss. A first through hole is provided in the middle of the positioning boss. The bottom end of the soy milk bucket is provided with a positioning recess that matches the positioning boss. A second through hole is provided in the middle of the positioning recess. The driving component is located below the positioning boss, and the driving shaft extends into the processing cavity through the first through hole; a heat insulation cover is provided around the driving shaft.

9. The detachable and washable soymilk maker according to any one of claims 1-7, characterized in that, The inner wall of the processing cavity is provided with a plurality of positioning spring pins, which are distributed at intervals in the circumferential direction of the processing cavity.

10. The detachable and washable soymilk maker according to any one of claims 1-7, characterized in that, The bottom of the soy milk container is made of stainless steel.