Double air duct suction and drying integrated mechanism for milk frothing machine

By introducing a dual-airflow design into the milk maker, the suction component removes moisture and the drying component dries the mixing chamber, solving the problems of milk powder getting damp and bacteria growing, thus improving the nutritional and hygienic level of the milk.

CN224320527UActive Publication Date: 2026-06-05宁波波咯咯母婴电器有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
宁波波咯咯母婴电器有限公司
Filing Date
2025-06-25
Publication Date
2026-06-05

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  • Figure CN224320527U_ABST
    Figure CN224320527U_ABST
Patent Text Reader

Abstract

The utility model provides a double air duct suction dries integrated mechanism for milk making machine relates to milk making machine technical field, including machine body, mixing storehouse, suction component and drying assembly, mixing storehouse detachable connection is in machine body, be provided with the powder inlet that communicates with mixing storehouse on machine body, be provided with suction port and drying air port respectively on powder inlet, suction component installs on machine body, and be provided with the suction passage that is used for intercommunication suction port and suction component on machine body, and through suction component is used for absorbing water vapor, drying assembly installs on machine body, and be provided with the drying passage that is used for intercommunication drying air port and drying assembly on machine body, and through drying assembly is used for drying to mixing storehouse, the utility model has the advantages of this mechanism through suction component absorbs and discharges from the water vapor in hot water in the top, through drying assembly from the hot air of discharging in the bottom carries out drying, further ensures the nutrition quality and health coefficient of milk water.
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Description

Technical Field

[0001] This utility model relates to the field of milk maker technology, and more specifically, to a dual-air duct suction and drying integrated mechanism for a milk maker. Background Technology

[0002] A formula maker is a household appliance that can automatically dispense formula powder, control water temperature, and prepare formula. It is widely used for preparing infant formula.

[0003] Currently, existing formula makers mix hot water and formula powder in a mixing chamber to prepare formula. However, during the preparation process, the hot water generates rising steam, which can enter the formula powder compartment as it falls. This can cause the formula powder to become damp and spoil, and over time, bacteria can easily grow inside the compartment. Furthermore, after the formula is prepared, some liquid residue remains on the inner wall of the mixing chamber, which can also harbor bacteria. These bacteria can then be mixed into the prepared formula, affecting its nutritional quality and hygiene, and ultimately impacting the baby's healthy growth. Utility Model Content

[0004] The technical problem this invention aims to solve is that existing milk maker machines are prone to bacterial growth during use, affecting the nutritional quality and hygiene of the milk. To overcome the shortcomings of the prior art, this invention provides a method that uses a suction component to remove water vapor generated by hot water, preventing it from entering the milk powder container. At the same time, a drying component facilitates the rapid drying of the liquid in the mixing container, preventing bacterial growth and further ensuring the nutritional quality and hygiene of the milk.

[0005] To achieve the purpose of this utility model, the following technical solution is adopted:

[0006] A dual-duct suction and drying integrated mechanism for a formula maker includes a body, a mixing chamber, a suction component, and a drying component. The mixing chamber is detachably connected to the body, which has a powder inlet communicating with it. The powder inlet has a suction port and a drying port. The suction component is mounted on the body, which has a suction channel connecting the suction port and the suction component, and the suction component absorbs moisture generated by hot water. The drying component is mounted on the body, which has a drying channel connecting the drying port and the drying component, and the drying component dries the mixing chamber. This mechanism absorbs and discharges moisture from the hot water from above using the suction component, preventing moisture from flowing into the formula chamber and ensuring its dryness. This prevents the formula from becoming damp, spoiling, or growing bacteria. The drying component discharges hot air from below, drying any remaining milk in the mixing chamber and preventing milk residue, further ensuring the nutritional quality and hygiene of the milk.

[0007] Preferably, the air intake is located above the powder inlet, and the drying air inlet is located below the powder inlet. This facilitates the upward absorption of moisture and the downward drying with hot air.

[0008] Preferably, the air intake includes a plurality of air intake through holes spaced circumferentially above the powder inlet. The air intake channel is located above the powder inlet, with the inlet end of each air intake through hole connected to the powder inlet and the outlet end of each air intake through hole connected to the air intake channel. The drying air intake includes a plurality of drying through holes spaced circumferentially below the powder inlet. The drying channel is located below the powder inlet, with the inlet end of each drying through hole connected to the drying channel and the outlet end of each drying through hole connected to the top opening of the mixing chamber. The circumferentially distributed air intake through holes ensure comprehensive absorption of moisture, further ensuring the comprehensiveness and effectiveness of absorption. The circumferentially distributed drying through holes ensure comprehensive drying of the mixing chamber, further ensuring the comprehensiveness and effectiveness of drying.

[0009] Preferably, a channel partition is provided on one side of the powder inlet inside the machine body, dividing the machine body into an air intake channel connected to the air intake and a drying channel connected to the drying air intake. The channel partition separates the air ducts to the left and right, which facilitates manufacturing and also makes it easy to distinguish the air ducts so that they can operate independently without interfering with each other.

[0010] Preferably, the top of the machine body is provided with a ventilation slot; the powder inlet is disposed through the bottom of the ventilation slot, and a first protruding cylinder is provided on the bottom of the ventilation slot at the powder inlet; the air intake and drying air intake are respectively located on the upper and lower sides of the first protruding cylinder; the channel partition is disposed on the bottom of the ventilation slot on one side in the left-right direction of the first protruding cylinder, and the channel partition divides the ventilation slot into an air intake area and a drying area; the air intake area is provided with an air intake communication hole communicating with the air intake assembly; an air intake sealing cover is detachably connected to the air intake area, and the air intake area is sealed by the air intake sealing cover to form an air intake channel; the drying area is provided with a drying communication hole communicating with the drying assembly; a drying sealing cover is detachably connected to the drying area, and the drying area is sealed by the drying sealing cover to form a drying channel. The ventilation duct is divided into a suction area and a drying area by a channel partition, which can separate the two areas. The suction sealing cover and the drying sealing cover can seal the respective areas to prevent interference during the suction and drying process. The detachable design further ensures the convenience of disassembly, assembly, maintenance and cleaning.

[0011] Preferably, the drying air outlet includes a plurality of drying through holes evenly distributed circumferentially along the outer peripheral wall of the first convex cylinder and disposed on the drying area, with each drying through hole connecting the drying area and the mixing chamber; the groove wall of the suction area is higher than the groove wall of the drying area; the drying sealing cover seals the drying area; a surrounding plate is provided on the top of the drying sealing cover, and the surrounding plate connects with the groove wall of the suction area that is higher than the drying area to form a new annular area; the drying sealing cover is provided with a first powder passage hole communicating with the first convex cylinder. By installing the drying sealing cover on the lower layer, it can be opened to the suction area of ​​the upper layer, ensuring better drying of the mixing chamber below, without interfering with the suction above, further improving the rationality of the structure.

[0012] Preferably, the top surface of the drying sealing cover has a second protruding cylinder that protrudes upward at the first powder passage hole; the air intake includes a plurality of drying through holes evenly distributed along the circumference of the second protruding cylinder on its outer peripheral wall; the air intake sealing cover seals the annular area enclosed by the drying sealing cover and the air intake area; the air intake sealing cover has a second powder passage hole communicating with the second protruding cylinder. The drying sealing cover facilitates the sealing of the upper area, thereby further ensuring the air intake effect, preventing air leakage, and also facilitating overall assembly and disassembly.

[0013] Preferably, the outer peripheral wall of the drying area is provided with a plurality of first sealing connection blocks; the outer peripheral wall of the drying sealing cover is provided with a first sealing groove that engages with the first sealing connection blocks; the outer peripheral wall of the suction area is provided with a plurality of second sealing connection blocks; the outer peripheral wall of the suction sealing cover is provided with a second sealing groove that engages with the second sealing connection blocks. Through the distribution of upper and lower layers and the snap-fit ​​assembly / disassembly method, the rationality of the structure and the convenience of assembly / disassembly are further improved, while also ensuring the airtightness of the channel and preventing air leakage.

[0014] Preferably, the suction assembly includes a suction fan and a suction / exhaust channel mounted on the machine body; the air inlet of the suction fan is connected to the air outlet of the suction channel; the air inlet of the suction channel is connected to the air inlet; the air inlet of the suction / exhaust channel is connected to the air outlet of the suction fan, and the air outlet of the suction / exhaust channel extends to the outside of the machine body; the drying assembly includes a heater and a drying fan mounted on the machine body; the air outlet of the heater is connected to the air inlet of the drying channel, and the air inlet of the drying channel is connected to the drying air inlet; the air inlet of the heater is connected to the air outlet of the drying fan, and the air inlet of the drying fan extends to the outside of the machine body; the suction fan facilitates better suction; the drying fan facilitates better drying.

[0015] Preferably, the machine body includes a main body and a cover; the cover is fixedly fitted over the main body, and the top surface of the cover has a milk powder hopper mounting slot; the bottom of the milk powder hopper mounting slot has a powder inlet; the powder inlet is located on the main body; the top of the powder inlet is connected to the bottom of the powder outlet, and the cover also has a powder outlet at the bottom of the powder inlet; the cover has a cover holding space below the powder outlet; L-shaped plug-in plates are symmetrically arranged on both sides of the bottom surface of the powder outlet on the cover; the mixing chamber has symmetrically arranged plug-in steps on both sides that engage with the L-shaped plug-in plates; the main body has a water inlet interface connected to the mixing water inlet of the mixing chamber at the cover holding space; the mixing chamber has a water inlet connector connected to the water inlet interface; the water inlet connector passes through the cover and connects to the water inlet interface. The cover ensures the overall aesthetics of the machine body, while the detachable mixing chamber facilitates further cleaning, further ensuring the hygiene of the milk.

[0016] In summary, the advantages of this invention are that the suction component absorbs and discharges water vapor from the hot water from above, thereby preventing water vapor from flowing into the milk powder container, ensuring the dryness of the milk powder container, preventing moisture absorption, spoilage, or bacterial growth, and the drying component discharges hot air from below, thereby drying the milk remaining in the mixing container, preventing milk residue from remaining in the mixing container, and further ensuring the nutritional quality and hygiene of the milk. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the dual-air duct suction and drying integrated mechanism for the milk maker of this utility model.

[0018] Figure 2 This is a structural schematic diagram of the front of the fuselage of this utility model.

[0019] Figure 3 This is a structural schematic diagram of the back of the fuselage of this utility model.

[0020] Figure 4 This is a cross-sectional view of the fuselage of this utility model.

[0021] Figure 5 This is an exploded view of the fuselage of this utility model.

[0022] Figure 6 This is a schematic diagram of the structure of the cover of this utility model.

[0023] Explanation of reference numerals in the attached figures:

[0024] 1. Body; 101. Body; 102. Cover; 103. Milk powder hopper mounting slot; 104. Powder outlet; 105. Powder outlet; 106. Cover holding gap; 107. L-shaped plug plate; 11. Powder inlet; 111. Air inlet; 112. Drying air inlet; 12. Air intake channel; 13. Drying channel; 14. Ventilation slot; 141. Air intake area; 1411. Air intake connecting hole; 142. Drying area; 1421. Drying connecting hole; 143. First sealing connection block; 144. Second sealing connection 15. First protruding cylinder; 16. Channel partition; 17. Suction sealing cover; 171. Second powder passage hole; 172. Second sealing groove; 18. Drying sealing cover; 181. Enclosure plate; 182. First powder passage hole; 183. Second protruding cylinder; 184. First sealing groove; 2. Mixing chamber; 20. Mixing water inlet; 201. Insertion step; 202. Water inlet connector; 3. Suction assembly; 31. Suction fan; 32. Suction and exhaust channel; 4. Drying assembly; 41. Heater; 42. Drying fan. Detailed Implementation

[0025] First, those skilled in the art should understand that these embodiments are merely used to explain the technical principles of the embodiments of this application and are not intended to limit the scope of protection of the embodiments of this application. Those skilled in the art can make adjustments as needed to adapt to specific application scenarios.

[0026] In the description of the embodiments of this application, it should be noted that, unless otherwise explicitly specified and limited, the terms "connected" and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; 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. Those skilled in the art can understand the specific meaning of the above terms in the embodiments of this application based on the specific circumstances.

[0027] In the embodiments of this application, unless otherwise expressly specified and limited, "above" or "below" the second feature can mean that the first feature is in direct contact with the second feature, or that the first feature is in indirect contact with the second feature through an intermediate medium. Furthermore, "above," "on top of," and "over" the second feature can mean that the first feature is directly above or diagonally above the second feature, or simply that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature can mean that the first feature is directly below or diagonally below the second feature, or simply that the first feature is at a lower horizontal level than the second feature.

[0028] The present application will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0029] like Figures 1 to 6As shown, a dual-duct suction and drying integrated mechanism for a milk powder maker includes a body 1, a mixing chamber 2, a suction component 3, and a drying component 4. The body 1 includes a body 101 and a cover 102. The cover 102 is fixedly fitted over the body 101 to ensure overall aesthetics. The top surface of the cover 102 is provided with a milk powder hopper mounting groove 103 for installing the milk powder hopper. The bottom of the milk powder hopper mounting groove 103 is provided with a powder discharge port 104 for discharging milk powder from the milk powder hopper. The body 101 is provided with a powder inlet 11 that communicates with the top opening of the mixing chamber 2. The top of the powder inlet 11 is connected to the bottom of the powder discharge port 104. The cover 102 is also provided with a powder outlet 105 at the bottom of the powder inlet 11 for dropping milk powder into the mixing chamber 2. The mixing chamber 2 is detachably connected to the cover 102, and the top opening of the mixing chamber 2 is connected to the powder outlet 105. A bottle-holding opening 106 is provided on the cover 102 below the mixing chamber 2 for holding baby bottles. In this embodiment, L-shaped plug-in plates 107 are symmetrically arranged on both sides of the bottom surface of the powder outlet 105 on the cover 102. Plug-in steps 201 are symmetrically arranged on both sides of the mixing chamber 2 to engage with the L-shaped plug-in plates 107. A water inlet interface is provided on the front side of the bottle-holding opening 106 on the body 101, which connects to the mixing water inlet 20 of the mixing chamber 2. A water inlet connector 202 is provided on the mixing chamber 2, which connects to the water inlet interface. The water inlet connector 202 passes through the cover 102 and connects to the water inlet interface. The horizontal plug-in method allows for easy assembly and disassembly of the mixing chamber 2, and also facilitates further cleaning of the mixing chamber 2, further ensuring the hygiene of the milk.

[0030] like Figures 2 to 5 As shown, an air intake 111 is provided at the upper part of the powder inlet 11, and an air intake assembly 3 is installed on the body 1. The body 1 is provided with an air intake channel 12 for connecting the air intake 111 and the air intake assembly 3, and the air intake assembly 3 is used to absorb water vapor generated by hot water. A drying air intake 112 is provided at the lower part of the powder inlet 11, and a drying assembly 4 is installed on the body 1. The body 1 is provided with a drying channel 13 for connecting the drying air intake 112 and the drying assembly 4, and the drying assembly 4 is used to dry the mixing chamber 2. This mechanism absorbs and discharges water vapor from the hot water from above through the air intake assembly 3, thereby preventing water vapor from flowing into the milk powder chamber, ensuring the dryness of the milk powder chamber, preventing moisture absorption, spoilage, or bacterial growth. The drying assembly 4 discharges hot air from below, thereby drying the milk remaining in the mixing chamber 2, preventing milk residue in the mixing chamber 2, and further ensuring the nutritional quality and hygiene of the milk.

[0031] like Figure 4 and Figure 5As shown, the air intake 111 includes several suction through holes spaced circumferentially on the upper part of the powder inlet 11. Suction channels 12 are distributed on the upper part of the powder inlet 11, with the inlet end of each suction through hole connected to the powder inlet 11 and the outlet end of each suction through hole connected to the suction channel 12. The circumferentially distributed suction through holes ensure comprehensive absorption of moisture, further ensuring the comprehensiveness and effectiveness of absorption. The drying air intake 112 includes several drying through holes spaced circumferentially on the lower part of the powder inlet 11; drying channels 13 are distributed on the lower part of the powder inlet 11, with the inlet end of each drying through hole connected to the drying channel 13 and the outlet end of each drying through hole connected to the top opening of the mixing chamber 2. The circumferentially distributed drying through holes ensure comprehensive drying of the mixing chamber 2, further ensuring the comprehensiveness and effectiveness of drying.

[0032] like Figure 4 and Figure 5 As shown, the top surface of the body 101 of the machine body 1 is provided with an upward-opening ventilation slot 14; the powder inlet 11 is vertically inserted through the bottom of the ventilation slot 14, and a first protruding cylinder 15 is provided on the bottom of the ventilation slot 14 at the powder inlet 11; the suction port 111 and the drying port 112 are respectively located on the upper and lower sides of the first protruding cylinder 15; an arc-shaped channel partition 16 is provided on the bottom of the ventilation slot 14 on the right side of the first protruding cylinder 15, and the channel partition 16 divides the ventilation slot 14 into a right-side suction area 141 and a left-side suction area 141. The drying area 142 and the suction area 141 are provided with suction communication holes 1411 that communicate with the suction assembly 3. A suction sealing cover 17 is detachably connected to the suction area 141, and the top of the suction area 141 is sealed by the suction sealing cover 17 to form a suction channel 12. The drying area 142 is provided with drying communication holes 1421 that communicate with the drying assembly 4. A drying sealing cover 18 is detachably connected to the drying area 142, and the top of the drying area 142 is sealed by the drying sealing cover 18 to form a drying channel 13. The suction area 141 and the drying area 142 are separated by the channel partition 16 on the ventilation slot 14, thereby separating the two areas. The suction sealing cover 17 and the drying sealing cover 18 can seal their respective areas to prevent interference during the suction and drying process. The detachable design further ensures the convenience of disassembly, assembly, maintenance and cleaning.

[0033] like Figure 4 and Figure 5As shown, the drying air vent 112 includes a plurality of drying through holes evenly distributed circumferentially along the bottom of the outer peripheral wall of the first protrusion 15 on the drying area 142, and each drying through hole is used to connect the drying area 142 and the mixing chamber 2; the groove wall of the suction area 141 is higher than the groove wall of the drying area 142; the drying sealing cover 18 seals the drying area 142; a surrounding plate 181 is provided on the top surface of the drying sealing cover 18, and the surrounding plate 181 connects with the groove wall of the suction area 141 that is higher than the drying area 142 to form a new annular area; the drying sealing cover 18 is provided with a first powder passage hole 182 that communicates with the first protrusion 15. By installing the drying sealing cover 18 on the lower layer, it can be separated from the upper suction area 141, ensuring better drying of the mixing chamber 2 below, and without interfering with the upper suction, further improving the rationality of the structure. The top surface of the drying sealing cover 18 has a second protruding cylinder 183 that protrudes upward at the first powder passage hole 182. The air intake 111 includes a plurality of drying through holes evenly distributed along the circumference of the second protruding cylinder 183 on its outer peripheral wall. The air intake sealing cover 17 seals the annular area enclosed by the drying sealing cover 18 and the air intake area 141. The air intake sealing cover 17 has a second powder passage hole 171 that communicates with the second protruding cylinder 183. The drying sealing cover 18 facilitates the sealing of the upper area, thereby further ensuring the air intake effect, preventing air leakage, and also facilitating the overall disassembly and assembly.

[0034] like Figures 2 to 5 As shown, in this embodiment, the disassembly method of the suction sealing cover 17 and the drying sealing cover 18 is as follows: a plurality of first sealing connecting blocks 143 are provided on the outer peripheral wall of the drying area 142; a first sealing groove 184 is provided on the outer peripheral wall of the drying sealing cover 18 to engage with the first sealing connecting blocks 143; a plurality of second sealing connecting blocks 144 are provided on the outer peripheral wall of the suction area 141; and a second sealing groove 172 is provided on the outer peripheral wall of the suction sealing cover 17 to engage with the second sealing connecting blocks 144. Through the distribution of the upper and lower layers and the snap-fit ​​disassembly method, the rationality of the structure and the convenience of disassembly are further improved, while also ensuring the sealing of the channel and preventing air leakage.

[0035] like Figure 3 and Figure 5 As shown, the suction assembly 3 includes a suction fan 31 and a suction-exhaust channel 32 mounted on the body 1. The air inlet of the suction fan 31 is connected to the air outlet of the suction channel 12. The air inlet of the suction channel 12 is connected to the air inlet 111. The air inlet of the suction-exhaust channel 32 is connected to the air outlet of the suction fan 31, and the air outlet of the suction-exhaust channel 32 extends to the outside of the body 1. The suction fan 31 facilitates better suction.

[0036] like Figure 2 and Figure 5 As shown, the drying assembly 4 includes a heater 41 and a drying fan 42 mounted on the machine body 1; the air outlet of the heater 41 is connected to the air inlet of the drying channel 13, and the air inlet of the drying channel 13 is connected to the drying air outlet 112; the air inlet of the heater 41 is connected to the air outlet of the drying fan 42, and the air inlet of the drying fan 42 is connected to the outside of the machine body 1. The drying fan 42 facilitates better drying effect.

[0037] The device feeds milk powder into the mixing chamber 2 through the milk powder hopper, while hot water enters the mixing chamber 2 through the mixing inlet 20. This allows the hot water and milk powder to mix and form milk. During mixing, the hot water generates steam. By turning on the suction fan 31, the circumferentially distributed air intakes 111 above the powder inlet 11 draw in the steam, preventing it from entering the milk powder hopper above and causing the milk powder to become damp and spoil. After mixing, the heater 41 and the drying fan 42 are turned on, causing the circumferentially distributed drying air intakes 112 below the powder inlet 11 to blow air, drying any remaining milk in the mixing chamber 2 and preventing bacterial growth.

[0038] In summary, the advantages of this invention are that the suction component 3 absorbs and discharges water vapor from the hot water from above, thereby preventing water vapor from flowing into the milk powder container, ensuring the dryness of the milk powder container, preventing moisture absorption, spoilage, or bacterial growth, and the drying component 4 discharges hot air from below, thereby drying the milk remaining in the mixing container 2, preventing milk residue in the mixing container 2, and further ensuring the nutritional quality and hygiene of the milk.

[0039] In the description of the embodiments of this application, it should be noted that the terms "inner" and "outer" and other terms indicating direction or positional relationship are based on the direction or positional relationship shown in the drawings. This is only for the convenience of description and does not indicate or imply that the device or component must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, it should not be construed as a limitation of this application.

[0040] In the description of this application, the references to terms such as "an embodiment," "some embodiments," "in this embodiment," "specific example," or "some examples," etc., refer to specific features, structures, materials, or characteristics described in connection with that embodiment or example, which are included in at least one embodiment or example of this application. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in a suitable manner in any one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of different embodiments or examples.

[0041] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A dual-duct suction and drying integrated mechanism for a milk maker, characterized in that, The system includes a body (1), a mixing chamber (2), a suction assembly (3), and a drying assembly (4). The mixing chamber (2) is detachably connected to the body (1), and the body (1) is provided with a powder inlet (11) that communicates with the mixing chamber (2). The powder inlet (11) is provided with a suction port (111) and a drying port (112). The suction assembly (3) is installed on the body (1), and the body (1) is provided with a suction channel (12) for connecting the suction port (111) and the suction assembly (3), and the suction assembly (3) is used to absorb water vapor generated by hot water. The drying assembly (4) is installed on the body (1), and the body (1) is provided with a drying channel (13) for connecting the drying port (112) and the drying assembly (4), and the drying assembly (4) is used to dry the mixing chamber (2).

2. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 1, characterized in that, The air intake (111) is located above the powder inlet (11); the drying air inlet (112) is located below the powder inlet (11).

3. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 2, characterized in that, The air intake (111) includes several air intake through holes arranged at intervals along the circumference on the upper part of the powder inlet (11), and the air inlet end of each air intake through hole is connected to the powder inlet (11), and the air outlet end of each air intake through hole is connected to the air intake channel (12); the drying air intake (112) includes several drying through holes arranged at intervals along the circumference on the lower part of the powder inlet (11), and the air inlet end of each drying through hole is connected to the drying channel (13), and the air outlet end of each drying through hole is connected to the top opening of the mixing chamber (2).

4. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 1, characterized in that, The machine body (1) is provided with a channel partition (16) on one side of the powder inlet (11), and the machine body (1) is divided into a suction channel (12) connected to the suction port (111) and a drying channel (13) connected to the drying port (112) by the channel partition (16).

5. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 4, characterized in that, The top of the machine body (1) is provided with a ventilation slot (14); the powder inlet (11) is provided through the bottom of the ventilation slot (14), and a first protruding cylinder (15) is provided on the bottom of the ventilation slot (14) at the powder inlet (11); the suction port (111) and the drying port (112) are respectively located on the upper and lower sides of the first protruding cylinder (15); the channel partition (16) is provided on the bottom of the ventilation slot (14) on one side of the first protruding cylinder (15) in the left and right direction, and the ventilation slot (14) is divided into a suction area (141) and a drying area (142) by the channel partition (16). The suction area (141) is provided with a suction communication hole (1411) that communicates with the suction assembly (3); a suction sealing cover plate (17) is detachably connected to the suction area (141), and the suction area (141) is sealed by the suction sealing cover plate (17) to form a suction channel (12); the drying area (142) is provided with a drying communication hole (1421) that communicates with the drying assembly (4); a drying sealing cover plate (18) is detachably connected to the drying area (142), and the drying area (142) is sealed by the drying sealing cover plate (18) to form a drying channel (13).

6. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 5, characterized in that, The drying air vent (112) includes a plurality of drying through holes evenly distributed circumferentially along the outer peripheral wall of the first protrusion (15) on the drying area (142), and each drying through hole is used to connect the drying area (142) and the mixing chamber (2); the groove wall of the suction area (141) is higher than the groove wall of the drying area (142); the drying sealing cover (18) seals the drying area (142); a surrounding plate (181) is provided on the top of the drying sealing cover (18), and the surrounding plate (181) connects with the groove wall of the suction area (141) that is higher than the drying area (142) to form a new annular area; the drying sealing cover (18) is provided with a first powder passage hole (182) that communicates with the first protrusion (15).

7. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 6, characterized in that, The top surface of the drying sealing cover (18) is provided with a second protruding cylinder (183) that protrudes upward at the first powder passage hole (182); the air intake (111) includes a plurality of drying through holes provided on the outer peripheral wall of the second protruding cylinder (183) and evenly distributed along the circumference of the second protruding cylinder (183); the air intake sealing cover (17) seals the annular area enclosed by the drying sealing cover (18) and the air intake area (141); the air intake sealing cover (17) is provided with a second powder passage hole (171) that communicates with the second protruding cylinder (183).

8. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 5, characterized in that, The drying area (142) has a plurality of first sealing connection blocks (143) on its outer peripheral wall; the drying sealing cover (18) has a first sealing groove (184) on its outer peripheral wall that engages with the first sealing connection blocks (143); the suction area (141) has a plurality of second sealing connection blocks (144) on its outer peripheral wall; the suction sealing cover (17) has a second sealing groove (172) on its outer peripheral wall that engages with the second sealing connection blocks (144).

9. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 1, characterized in that, The suction assembly (3) includes a suction fan (31) and a suction and exhaust channel (32) mounted on the body (1); the air inlet of the suction fan (31) is connected to the air outlet of the suction channel (12); the air inlet of the suction channel (12) is connected to the air inlet (111); the air inlet of the suction and exhaust channel (32) is connected to the air outlet of the suction fan (31), and the air outlet of the suction and exhaust channel (32) is connected to the machine. Outside the body (1); the drying assembly (4) includes a heater (41) and a drying fan (42) installed on the body (1); the air outlet of the heater (41) is connected to the air inlet of the drying channel (13), and the air inlet of the drying channel (13) is connected to the drying air outlet (112); the air inlet of the heater (41) is connected to the air outlet of the drying fan (42), and the air inlet of the drying fan (42) is connected to the outside of the body (1).

10. The dual-duct suction and drying integrated mechanism for a milk maker according to claim 1, characterized in that, The machine body (1) includes a body (101) and a cover (102); the cover (102) is fixedly fitted outside the body (101), and a milk powder hopper mounting groove (103) is provided on the top surface of the cover (102); a powder outlet (104) is provided at the bottom of the milk powder hopper mounting groove (103); the powder inlet (11) is provided on the body (101); the top of the powder inlet (11) is connected to the bottom of the powder outlet (104), and a powder outlet (105) is also provided on the cover (102) at the bottom of the powder inlet (11); the mixing chamber (2) is detachably connected to the cover (102), and the cover (102) has... A machine cover holding gap (106) is provided below the mixing chamber (2); L-shaped plug-in plates (107) are symmetrically arranged on both sides of the bottom surface of the powder outlet (105) on the machine cover (102); plug-in steps (201) that are symmetrically arranged on both sides of the mixing chamber (2) to be plugged into the L-shaped plug-in plates (107); a water inlet interface connected to the mixing water inlet (20) of the mixing chamber (2) is provided on the machine body (101) at the machine cover holding gap (106); a water inlet connector (202) connected to the water inlet interface is provided on the mixing chamber (2); the water inlet connector (202) passes through the machine cover (102) and connects to the water inlet interface.