A soymilk machine
By installing a separation cover inside the soymilk maker and using a combination of a connecting plate and a filter screen, the problem of insufficient grinding of soybeans is solved, and the soymilk and soy pulp are effectively separated, thus improving the taste and quality of the soymilk.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHONGSHAN DEMAX INTELLIGENT KITCHEN EQUIPMENT CO LTD
- Filing Date
- 2025-04-18
- Publication Date
- 2026-06-09
AI Technical Summary
Traditional soy milk makers do not grind the beans sufficiently during the grinding process, resulting in a lot of soy pulp and affecting the taste of the soy milk.
A separation hood is installed inside the processing chamber of the soy milk maker. The separation hood consists of a connecting plate and a filter screen, forming a grinding chamber section and a separation chamber section. The grinding efficiency is improved by the rotation of the stirring components and the impact force of the connecting plate, and the soy milk and soy residue are separated by the filter screen.
It improves the grinding efficiency of soybeans, ensures effective separation of soy milk and soy pulp, and enhances the taste and quality of soy milk.
Smart Images

Figure CN224330837U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of soy milk maker technology, and in particular to a soy milk maker. Background Technology
[0002] A soy milk maker automatically mixes, stirs, and heats soybeans and water to make soy milk. It has a wide range of applications, suitable for everyday home use, as well as for soy milk shops and restaurant chains. Traditional soy milk makers, especially the bucket-type soy milk makers used in soy milk shops or restaurants, usually grind the soybeans directly in the bucket, resulting in insufficient grinding of the soybeans and a large amount of soy pulp, which indirectly affects the taste of the soy milk. Utility Model Content
[0003] In order to overcome at least one of the defects of the prior art, the present invention provides a soy milk maker, which improves the grinding efficiency of soybeans by setting a separation cover in the processing chamber, and at the same time effectively isolates soybean residue and improves the taste of soy milk.
[0004] The technical solution adopted by this utility model to solve its problem is:
[0005] A soy milk maker, comprising:
[0006] The machining base has a machining cavity;
[0007] A separation cover is provided at a distance from the inner wall of the processing chamber, and the processing chamber is divided into a grinding chamber section and a separation chamber section. The separation cover includes multiple connecting plates and multiple filter screens. Each pair of adjacent filter screens is connected by a connecting plate and enclosed to form the separation cover. The filter screens are used to filter soybean residue and guide soybean milk to flow from the grinding chamber section to the separation chamber section.
[0008] A stirring assembly, comprising a stirring element and a driving element, wherein the stirring element is rotatably disposed in the grinding chamber section, and the driving element is used to drive the stirring element to rotate.
[0009] Furthermore, the bottom of the separation cover is provided with a connecting piece, which extends circumferentially along the separation cover. The connecting piece is provided with a limiting groove, and the bottom of the processing seat is provided with a limiting member. The limiting member is used to engage with the limiting groove after the separation cover is installed in the processing cavity to lock or unlock the separation cover.
[0010] Furthermore, the limiting groove includes a first groove segment and a second groove segment, the inner diameter of the first groove segment is larger than the inner diameter of the second groove segment, and it communicates with the second groove segment; the limiting member includes a limiting post and a limiting head, the limiting post passes through the first groove segment and is used to extend into the second groove segment when the separation cover rotates, and the limiting head is used to abut against the end wall of the second groove segment after the limiting post extends into the second groove segment.
[0011] Furthermore, the separation cover is also provided with a baffle plate, which is located inside the grinding chamber section.
[0012] Furthermore, the processing cavity is provided with a cover plate, the cover plate is provided with a first connecting part and a second connecting part, the processing seat is provided with a third connecting part and a fourth connecting part, the first connecting part and the third connecting part are detachably connected so that the cover plate can cover or open the processing cavity; the second connecting part is used to engage with the fourth connecting part after the cover plate covers the processing cavity to lock the cover plate.
[0013] Furthermore, the first connecting portion includes a first magnetic attracting member, and the third connecting portion includes a second magnetic attracting member, wherein the first magnetic attracting member and the second magnetic attracting member are magnetically attracted to each other.
[0014] Furthermore, the processing base is also equipped with a Hall sensor, which is used to send a signal after the first magnetic component and the second magnetic component are magnetically attracted together.
[0015] Furthermore, the second connecting part is a snap-fit groove provided on the cover plate, and the snap-fit groove extends along the circumference of the cover plate; the fourth connecting part is a buckle provided on the processing seat, the buckle includes a buckle body and a buckle hook, the buckle body is rotatably connected to the processing seat, one end of the buckle hook is connected to the buckle body, and the other end of the buckle hook is used to snap into the snap-fit groove after the cover plate covers the processing cavity, so as to lock the cover plate.
[0016] Furthermore, the processing cavity is equipped with two liquid level detectors, which are distributed vertically and horizontally within the processing cavity and are used to detect the liquid level.
[0017] Furthermore, it also includes a heating element disposed in the processing cavity, the heating element being used for heating.
[0018] In summary, the soy milk maker provided by this utility model has the following technical effects:
[0019] In use, the processing chamber is divided into a grinding chamber and a separation chamber by setting a separation hood inside the processing chamber. The stirring component is placed in the grinding chamber. When the driving component drives the stirring component to rotate, the stirring component will drive the mixture of beans and water to rotate at high speed. Since the separation hood is composed of a connecting plate and a filter screen, the beans will continuously hit the connecting plate during high-speed rotation, gaining additional force. Under the dual action of stirring force and impact force of the connecting plate, the grinding is more thorough and the grinding effect is improved. At the same time, since the filter screen has a specific pore size, smaller soy milk liquid molecules can flow into the separation chamber, while soy pulp particles are blocked in the grinding chamber, realizing the separation of soy milk and soy pulp and improving the taste of soy milk. Attached Figure Description
[0020] Figure 1 This is an exploded view of the structure of this utility model;
[0021] Figure 2 This is a schematic diagram of the structure of this utility model;
[0022] Figure 3 This is a cross-sectional view of the structure of this utility model.
[0023] The meanings of the reference numerals in the attached figures are as follows:
[0024] 10. Machining base; 11. Machining cavity; 12. Third connecting part; 13. Fourth connecting part; 14. Separation cavity section; 20. Separation cover; 21. Filter screen; 22. Connecting plate; 23. Grinding cavity section; 30. Cover plate; 31. First connecting part; 32. Second connecting part. Detailed Implementation
[0025] To better understand and implement this invention, the technical solutions in the embodiments of this invention will be clearly and completely described below with reference to the accompanying drawings.
[0026] In the description of this utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", and "outer" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0027] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.
[0028] See Figures 1 to 3 This utility model discloses a processing seat 10, a separation cover 20, and a stirring assembly. The processing seat 10 has a processing cavity 11. The separation cover 20 is spaced apart from the inner wall of the processing cavity 11, and the processing cavity 11 is divided into a grinding cavity section 23 and a separation cavity section 14. The separation cover 20 includes multiple connecting plates 22 and multiple filter screens 21. Each pair of adjacent filter screens 21 are connected by a connecting plate 22 and enclosed to form the separation cover 20. The filter screens 21 are used to filter soybean residue and guide soybean milk to flow through the grinding cavity section 23 to the separation cavity section 14. The stirring assembly includes a stirring element and a driving element. The stirring element is rotatably disposed in the grinding cavity section 23, and the driving element is used to drive the stirring element to rotate.
[0029] Based on the above structure, since the separation cover 20 and the inner wall of the processing cavity 11 are spaced apart, the processing cavity 11 is divided into two parts to form a grinding cavity section 23 and a separation cavity section 14. The stirring element is placed in the grinding cavity section 23, and the driving element is placed in the processing cavity 11 and connected to the stirring element to drive the stirring element to rotate in the grinding cavity section 23, so as to grind the beans inside the grinding cavity section 23 by the rotation of the stirring element.
[0030] Specifically, when the stirring element rotates in the grinding chamber 23, the mixture of beans and water moves at high speed in the grinding chamber 23 under the action of the stirring element. Since the separation cover 20 is formed by a combination of multiple connecting plates 22 and a filter screen 21, the beans will continuously collide with the multiple connecting plates 22 during the high-speed movement and receive the reaction force from the connecting plates 22. This is equivalent to providing additional extrusion force to the beans on the basis of the grinding force applied by the stirring component, so that the beans can be more fully crushed under the dual action of the stirring force and the force from the connecting plates 22, thus improving the grinding effect of the beans.
[0031] Meanwhile, because the filter screen 21 has a mesh structure with a specific pore size, during the process of the soybeans being stirred and ground into a soy milk mixture, the soy milk liquid molecules are small and can flow smoothly through the mesh of the filter screen 21 to the separation chamber 14. However, the soybean residue particles formed after grinding are larger and cannot pass through the mesh, so they are blocked by the filter screen 21 in the grinding chamber 23, thereby separating the soy milk from the soybean residue, filtering out the soybean residue, and improving the taste of the soy milk.
[0032] Compared to the separation cover 20, which is entirely composed of filter screens 21, although separation can also be achieved, the filter screens 21 are usually quite fine and soft, and may be insufficient in terms of strength and stability when used alone. Furthermore, due to the lack of a connecting plate 22 to assist in the grinding process, the soybean residue particles may be larger, affecting the taste of the soy milk and the separation effect. Therefore, in this embodiment, the separation cover 20 is formed by combining a connecting plate 22 and a filter screen 21. The connecting plate 22 can be used to assist in grinding, and the specific pore size on the filter screen 21 allows smaller soy milk liquid molecules to flow into the separation chamber section 14, while blocking the soybean residue particles in the grinding chamber section 23, thus achieving the purpose of separation, improving the grinding effect of the soybeans, and also separating the soybean residue, thereby improving the taste of the soy milk.
[0033] It should be noted that the separation cover 20 in this embodiment can be made of existing stainless steel wire mesh or nylon filter mesh, while the connecting plate 22 is made of high-strength stainless steel plate, aluminum alloy plate, or plastic segment made of polypropylene (PP) or polycarbonate (PC). During assembly, the filter mesh 21 and the connecting plate 22 are connected by welding or hot-melt connection to form the separation cover 20. The separation cover 20 can be installed in the processing cavity 11 by threaded connection, snap-fit or welding.
[0034] In addition, the stirring component in this embodiment can be an existing stirring blade or stirring blade used for grinding beans, while the driving component can be an existing driving motor, such as a DC motor or an AC motor.
[0035] Furthermore, the bottom of the separation cover 20 is provided with a connecting piece, which extends along the circumference of the separation cover 20. The connecting piece is provided with a limiting groove, and the bottom of the processing base 10 is provided with a limiting member. After the separation cover 20 is installed in the processing cavity 11, the limiting member cooperates with the limiting groove to lock or unlock the separation cover 20.
[0036] Specifically, when it is necessary to connect the separation cover 20 to the processing chamber 11, the limiting groove on the connecting piece can be aligned with the limiting member at the bottom of the processing chamber 11, and then an external force is applied downward to make the limiting member snap into the limiting groove and cooperate with the limiting groove to lock the separation cover 20. In this way, the separation cover 20 will not be displaced or shaken due to the impact force or vibration generated by the high-speed rotation of the mixture driven by the stirring component, thus ensuring the stability of the separation cover 20 and ensuring the stability and reliability of the separation process of soy milk and soy residue. When it is necessary to disassemble the separation cover 20, simply apply an external force to the separation cover 20 again to separate the limiting member from the limiting groove, and the separation cover 20 can be easily removed to facilitate cleaning, maintenance or replacement of the separation cover 20, grinding chamber section 23 and separation chamber section 14.
[0037] It should be noted that the limiting component in this embodiment can be an elastic buckle. During assembly, the limiting groove is brought close to the limiting component and aligned. Then, the operator applies external force to the separation cover 20. At this time, the limiting component undergoes elastic deformation under the pressure of the groove wall. When the limiting groove reaches the appropriate position, the limiting component returns to its original shape and is locked into the limiting groove. When unlocking, the limiting component is pressed or moved to deform it again and disengage it from the limiting groove.
[0038] Of course, the limiting component can also be composed of bolts and nuts. The bolts are fixed to the bottom of the machining base 10, and the nuts can be screwed onto the bolts. In this case, the limiting groove on the connecting piece can be set as an elongated hole to accommodate the installation of the bolts. When installing the separation cover 20, align the limiting groove with the bolts so that the bolts pass through the limiting grooves, and then tighten the nuts to firmly fix the separation cover 20 onto the machining base 10 to achieve locking. When unlocking, simply loosen the nuts to remove the separation cover 20.
[0039] Furthermore, the limiting groove includes a first groove segment and a second groove segment. The inner diameter of the first groove segment is larger than the inner diameter of the second groove segment and it communicates with the second groove segment. The limiting component includes a limiting post and a limiting head. The limiting post passes through the first groove segment and is used to extend into the second groove segment when the separation cover 20 rotates. The limiting head abuts against the end wall of the second groove segment after the limiting post extends into the second groove segment.
[0040] Based on this structure, the limiting member in this embodiment is formed by a combination of a limiting post and a limiting head, and the outer diameter of the limiting head is larger than the outer diameter of the limiting post. During installation, because the inner diameter of the first groove is larger, both the limiting post and the limiting head can be inserted into the first groove, which serves to initially fix the separation cover 20. Then, the separation cover 20 is rotated so that the limiting post extends into the second groove with a smaller inner diameter. At this time, the limiting head with a larger outer diameter can abut against the groove wall of the second groove to prevent the limiting post from coming out of the second groove. This makes it difficult for the separation cover 20 to move or detach during operation, improving the reliability of the connection. When disassembling, the separation cover 20 can be easily removed by simply rotating it in the opposite direction so that the limiting post returns from the second groove to the first groove, without the need for complicated tools or operating steps.
[0041] It should be noted that in this embodiment, the outer diameter of the limiting post is the same as the inner diameter of the second groove segment, so that after it slides into the second groove segment, it can abut against the inner wall of the second groove segment to achieve initial fixation. The outer diameter of the limiting head is larger than that of the second groove segment, so that after it extends into the second groove segment with the limiting post, it can abut against the outer periphery of the second groove segment to avoid the probability of the limiting post detaching from the second groove segment.
[0042] Furthermore, the separation cover 20 is also equipped with a baffle plate, which is located inside the grinding chamber section 23.
[0043] Specifically, the baffle plate can be protruding on the inner wall of the separation hood 20. When the fluid formed by the mixture of beans and water in the grinding chamber section 23 flows through the baffle plate, the baffle plate will directly block part of the fluid's flow path. The fluid can no longer flow along the original straight line or smooth curve, but is forced to bypass the baffle plate, thus forming a diversion around the baffle plate. This diversion changes the flow direction of the fluid, turning the original single-direction flow into multi-direction flow, making the material flow state in the grinding chamber more complex. The material is forced to flow along the unique path formed by the baffle plate, increasing the contact opportunities with the grinding components (such as the stirring components and the inner wall of the grinding chamber), thereby achieving more thorough grinding and further improving the grinding effect.
[0044] It should be noted that the baffle in this embodiment can be an existing straight-plate type baffle, such as a rectangular straight plate, which is installed vertically or obliquely on the inner wall of the separation shroud 20; or a spiral type baffle, which is spirally wrapped around the inner wall of the separation shroud 20.
[0045] Furthermore, the processing cavity 11 is provided with a cover plate 30, the cover plate 30 is provided with a first connecting part 31 and a second connecting part 32, the processing seat 10 is provided with a third connecting part 12 and a fourth connecting part 13, the first connecting part 31 and the third connecting part 12 are detachably connected so that the cover plate 30 can cover or open the processing cavity 11, and the second connecting part 32 is engaged with the fourth connecting part 13 after the cover plate 30 covers the processing cavity 11 to lock the cover plate 30.
[0046] Based on this structure, when in use, the first connecting part 31 is connected to the third connecting part 12, and then the second connecting part 32 is connected to the fourth connecting part 13 so that the cover plate 30 and the processing seat 10 are double locked, thereby more securely sealing the processing cavity 11, reducing the probability of the cover plate 30 tilting or not sealing properly due to external force, and reducing the risk of external dust falling into the processing cavity 11 during processing.
[0047] When it is necessary to open the processing chamber 11 for cleaning or pouring out soy milk, simply detach the second connecting part 32 from the fourth connecting part 13, and then detach the first connecting part 31 from the third connecting part 12, so that the cover plate 30 can be removed from the processing seat 10, and the processing chamber 11 can be opened for cleaning or maintenance of the internal components.
[0048] In this embodiment, there are multiple options for the connection between the cover plate 30 and the processing base 10. Specifically, the first connecting part 31 and the second connecting part 32 can be structures such as buckles, hooks, and blocks on the cover plate 30, while the third connecting part 12 and the fourth connecting part 13 can be set as slots or holes on the processing base 10 that engage with the first connecting part 31 and the second connecting part 32 respectively. Alternatively, buckles, hooks, blocks, etc. can be set on the processing base 10, and corresponding slots or holes can be set on the cover plate 30.
[0049] On the other hand, the connection structure can also be magnetic, such as the first connecting part 31 and the second connecting part 32 being magnetic components on the cover plate 30, while the third connecting part 12 and the fourth connecting part 13 are magnets on the processing base 10 that magnetically engage with the first connecting part 31 and the second connecting part 32, respectively; conversely, it is also feasible to set the magnetic components on the processing base 10 and the magnets on the cover plate 30, depending on the actual needs.
[0050] Preferably, in this embodiment, the first connecting part 31 includes a first magnetic member, and the third connecting part 12 includes a second magnetic member, with the first magnetic member and the second magnetic member magnetically engaging.
[0051] Specifically, the first magnetic component can be a permanent magnet made of materials such as ferrite or neodymium iron boron, while the second magnetic component can also be made of a permanent magnet material that magnetically attracts it. Alternatively, the first magnetic component can be an existing electromagnet that generates a magnetic field by passing an electric current through it, while the second magnetic component can be a permanent magnet. When the electromagnet is energized, it attracts the permanent magnet; when the power is off, the magnetic attraction disappears, facilitating quick separation of the components.
[0052] Compared to traditional mechanical connection methods, such as bolt connections and snap-fit connections, magnetic connections do not require tools. Simply bring the parts with magnetic attachments close together, and they will automatically attract each other under the action of magnetism, enabling quick installation. When disassembling, simply apply a certain external force to overcome the magnetism, and the parts can be easily separated, greatly improving the efficiency of installation and disassembly.
[0053] Furthermore, the machining base 10 is also equipped with a Hall sensor, which sends a signal after the first magnetic component and the second magnetic component are magnetically engaged.
[0054] Specifically, when the first magnetic component and the second magnetic component successfully magnetically engage, the Hall sensor detects the change in magnetic field and sends a signal to the controller on the processing base 10, indicating that the cover plate 30 and the processing base 10 are installed in place. This prompts the user to activate the drive component to start the stirring action, ensuring that the equipment only starts working when the cover plate 30 and the processing base 10 are installed in place. This avoids dangerous situations such as soy milk splashing or parts loosening and falling out during the soy milk making process due to the cover plate 30 not being installed correctly, effectively protecting the user's personal safety.
[0055] Preferably, the Hall sensor in this embodiment can be an existing linear Hall sensor or a switch-type Hall sensor, etc.
[0056] Furthermore, the second connecting part 32 is a snap-fit groove provided on the cover plate 30, which extends circumferentially along the cover plate 30. The fourth connecting part 13 is a buckle provided on the processing base 10. The buckle includes a buckle body and a buckle hook. The buckle body is rotatably connected to the processing base 10. One end of the buckle hook is connected to the buckle body. The other end of the buckle hook is snapped into the snap-fit groove after the cover plate 30 covers the processing cavity 11, so as to lock the cover plate 30.
[0057] Specifically, after the first connecting part 31 is connected to the third connecting part 12, an external force is applied to the hook in the direction of the cover plate 30, causing it to engage with the cover plate 30 in the engagement groove. Then, the buckle body is rotated downwards until the hook tightly engages with the engagement groove, further locking the cover plate 30 and thus more securely sealing the processing cavity 11, preventing the cover plate 30 from tilting or failing to seal properly due to uneven force. In addition, since the engagement groove extends circumferentially along the cover plate 30, the buckle is easier to align and engage during installation, eliminating the need for precise alignment of a specific position and reducing installation difficulty.
[0058] It should be noted that both the buckle body and the processing base 10 can be connected by a rotating shaft. During assembly, rubber washers, damping oil, etc. can be used on the outer circumference of the rotating shaft to increase the friction between the rotating shaft and the buckle body. After the hook is inserted into the locking groove, the user can rotate the buckle body downward until the hook is tightly hooked into the inner wall of the locking groove. At this time, the friction at the rotating shaft can resist the reverse tendency of the buckle body caused by vibration or other external forces, so that the hook is stably locked in the locking groove.
[0059] Furthermore, two liquid level detectors are provided in the processing cavity 11. The two liquid level detectors are distributed vertically and horizontally in the processing cavity 11 and are used to detect the liquid level respectively.
[0060] Specifically, by distributing two liquid level detectors vertically, the lower liquid level detector can be set to the lowest liquid level threshold. When the water level is below this value, the soymilk maker can stop working or issue an alarm to prevent the heating element from burning out due to low water level, which could damage the machine or even cause a safety accident. The upper liquid level detector can be set to the highest liquid level threshold. When the water level reaches or exceeds this value, the soymilk maker stops adding water to prevent soymilk from overflowing, thus preventing short circuits and other problems caused by overflow and extending the lifespan of the soymilk maker.
[0061] Preferably, the liquid level detector in this embodiment can be an existing float-type liquid level detector or a hydrostatic liquid level detector, etc.
[0062] More specifically, the processing chamber 11 is also equipped with a heating element, which can be an existing electric heating tube or an electromagnetic heating coil. The heating element heats the soy milk, destroying harmful substances in the soy milk and thus improving the safety of the soy milk.
[0063] 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 soy milk maker, characterized in that, include: The machining base has a machining cavity; A separation cover is provided at a distance from the inner wall of the processing chamber, and the processing chamber is divided into a grinding chamber section and a separation chamber section. The separation cover includes multiple connecting plates and multiple filter screens. Each pair of adjacent filter screens is connected by a connecting plate and enclosed to form the separation cover. The filter screens are used to filter soybean residue and guide soybean milk to flow from the grinding chamber section to the separation chamber section. A stirring assembly, comprising a stirring element and a driving element, wherein the stirring element is rotatably disposed in the grinding chamber section, and the driving element is used to drive the stirring element to rotate.
2. The soymilk maker as described in claim 1, characterized in that, The bottom of the separation cover is provided with a connecting piece, which extends circumferentially along the separation cover. The connecting piece is provided with a limiting groove. The bottom of the processing seat is provided with a limiting member, which is used to limit and cooperate with the limiting groove after the separation cover is installed in the processing cavity, so as to lock or unlock the separation cover.
3. The soy milk maker as described in claim 2, characterized in that, The limiting groove includes a first groove segment and a second groove segment. The inner diameter of the first groove segment is larger than the inner diameter of the second groove segment and it communicates with the second groove segment. The limiting member includes a limiting post and a limiting head. The limiting post passes through the first groove segment and is used to extend into the second groove segment when the separation cover rotates. The limiting head is used to abut against the end wall of the second groove segment after the limiting post extends into the second groove segment.
4. The soy milk maker as described in claim 1, characterized in that, The separation cover is also provided with a baffle plate, which is located inside the grinding chamber section.
5. The soymilk maker as described in claim 1, characterized in that, The processing cavity is provided with a cover plate, the cover plate is provided with a first connecting part and a second connecting part, the processing seat is provided with a third connecting part and a fourth connecting part, the first connecting part and the third connecting part are detachably connected so that the cover plate can cover or open the processing cavity; the second connecting part is used to engage with the fourth connecting part after the cover plate covers the processing cavity to lock the cover plate.
6. The soymilk maker as described in claim 5, characterized in that, The first connecting part includes a first magnetic element, and the third connecting part includes a second magnetic element, wherein the first magnetic element and the second magnetic element are magnetically attracted to each other.
7. The soymilk maker as described in claim 6, characterized in that, The processing base is also equipped with a Hall sensor, which is used to send a signal after the first magnetic component and the second magnetic component are magnetically attracted together.
8. The soymilk maker as described in claim 5, characterized in that, The second connecting part is a snap-fit groove provided on the cover plate, which extends circumferentially along the cover plate; the fourth connecting part is a buckle provided on the processing base, which includes a buckle body and a hook. The buckle body is rotatably connected to the processing base, one end of the hook is connected to the buckle body, and the other end of the hook is used to snap into the snap-fit groove after the cover plate covers the processing cavity, so as to lock the cover plate.
9. The soymilk maker according to any one of claims 1-8, characterized in that, The processing chamber is equipped with two liquid level detectors, which are distributed vertically and horizontally within the processing chamber and are used to detect the liquid level.
10. The soymilk maker according to any one of claims 1-8, characterized in that, It also includes a heating element, which is disposed in the processing cavity and is used for heating.