A top ventilation structure of a feeding bottle cleaning machine

CN224403597UActive Publication Date: 2026-06-26GUANGDONG YUELONG YOUDIELECTRIC APPLIANCE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG YUELONG YOUDIELECTRIC APPLIANCE CO LTD
Filing Date
2025-07-31
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The water vapor produced by the baby bottle washing machine condenses into condensate, which can easily accumulate on the outside of the machine casing, leading to safety hazards such as electrical leakage and other accidents.

Method used

A top ventilation structure for a baby bottle cleaner is designed, including a housing and a top cover. Condensate is collected through a converging chamber, and a smooth steam discharge channel is provided by an exhaust chamber and an exhaust port design. Combined with multi-layer anti-splash baffles and diffusion channels, condensate is prevented from splashing out.

Benefits of technology

It effectively prevents condensate from accumulating on the outside of the machine casing, reduces safety hazards, ensures smooth steam discharge, and maintains internal pressure balance and drying effect.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224403597U_ABST
    Figure CN224403597U_ABST
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Abstract

The utility model discloses a kind of milk bottle cleaning machine top ventilation structure, including cabinet, it includes top surface, the convergent cavity of being recessed on the top surface, and the ventilation hole of being through the convergent cavity;Top cover, it is used to cover on the convergent cavity, to make condensate water drop to the convergent cavity;The cabinet and the top cover form the exhaust cavity that the ventilation hole is communicated, and the exhaust hole of the top cover is equipped with the exhaust cavity being communicated.The utility model provides a kind of milk bottle cleaning machine top ventilation structure, by using top cover so that water vapor meets cold, to produce condensate water on top cover, condensate water low falls to convergent cavity, backflow to ventilation hole, both can avoid condensate water to generate in cabinet outside, also can collect condensate water.
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Description

Technical Field

[0001] This application relates to the field of baby bottle cleaning machine technology, and in particular to a top ventilation structure for a baby bottle cleaning machine. Background Technology

[0002] The water vapor produced by the bottle washing machine can easily form condensation, causing water accumulation around it and even leading to safety accidents such as electric leakage. Utility Model Content

[0003] To solve the above problems, this technical solution provides a breathable structure at the top of a baby bottle washing machine.

[0004] To achieve the above objectives, the technical solution is as follows:

[0005] A ventilated structure for the top of a baby bottle washer, including

[0006] The housing includes a top surface, a flow-gathering cavity recessed on the top surface, and a vent hole penetrating the flow-gathering cavity;

[0007] A top cover is used to cover the collection chamber so that condensate drips into the collection chamber;

[0008] An exhaust chamber is formed between the housing and the top cover, which communicates with the vent hole. The top cover is provided with an exhaust hole that communicates with the exhaust chamber.

[0009] As described above, the top ventilation structure of a baby bottle cleaner includes a bottom surface and an inclined surface that gradually slopes from the top surface toward the bottom surface.

[0010] As described above, the top ventilation structure of a baby bottle cleaner includes a first splash guard and a second splash guard on the flow-gathering cavity. The first splash guard is located on the left and right sides of the vent hole, and the second splash guard is located on the front and rear sides of the vent hole.

[0011] As described above, the top ventilation structure of a baby bottle cleaner is further provided with a third splash guard and a fourth splash guard on the flow-gathering cavity. The third splash guard is located on the left and right sides of the first splash guard, and the fourth splash guard is located on the front and rear sides of the second splash guard.

[0012] In the bottle washing machine top ventilation structure described above, the length of the third splash guard is greater than the length of the first splash guard, and the length of the fourth splash guard is greater than the length of the second splash guard.

[0013] In the bottle washing machine top ventilation structure described above, the third splash guard and the fourth splash guard are located on the upper side of the inclined surface, and the first splash guard and the second splash guard are located on the lower side of the inclined surface or on the bottom surface.

[0014] As described above, a top ventilation structure for a baby bottle cleaner includes a first turning gap between the first splash guard and the second splash guard, a second turning gap between the third splash guard and the fourth splash guard, and a first turning baffle corresponding to the outer side of the first turning gap and a second turning baffle corresponding to the outer side of the second turning gap on the top cover.

[0015] As described above, the top ventilation structure of a baby bottle cleaner has a connecting post on the flow-gathering cavity and a handle on the top cover, with the handle connected to the connecting post by screws.

[0016] As described above, in a bottle washing machine top ventilation structure, the exhaust port is located on the periphery of the top cover, and there is a diffusion channel communicating with the exhaust port between the periphery of the top cover and the periphery of the flow-gathering cavity.

[0017] The beneficial effects of this application are:

[0018] This utility model provides a top ventilation structure for a baby bottle cleaner. By utilizing the top cover, water vapor is cooled, resulting in condensation on the top cover. The condensation falls into the collection chamber and then flows back into the ventilation hole. This not only prevents condensation from being generated outside the machine casing but also collects the condensation. Attached Figure Description

[0019] To more clearly illustrate the technical solutions in the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below.

[0020] Figure 1 Structural decomposition of this application Figure 1 ;

[0021] Figure 2 Structural decomposition of this application Figure 2 ;

[0022] Figure 3 This is a diagram of the internal structure of this application. Detailed Implementation

[0023] To make the technical problems solved, technical solutions, and beneficial effects of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.

[0024] A ventilated structure for the top of a baby bottle washer, including

[0025] The housing 1 includes a top surface 11, a flow-gathering cavity 12 recessed on the top surface 11, and a vent hole 13 penetrating the flow-gathering cavity 12.

[0026] Top cover 2, which is used to cover the collection cavity 12 so that condensate drips into the collection cavity 12;

[0027] An exhaust chamber 3 is formed between the housing 1 and the top cover 2, communicating with the vent 13. The top cover 2 is provided with an exhaust hole 21 communicating with the exhaust chamber 3. The condensate on the top cover is collected and guided by the converging chamber to prevent it from dripping randomly or affecting the ventilation function. At the same time, the design of the exhaust chamber and the exhaust hole provides a smooth steam discharge channel, ensuring pressure balance and drying effect inside the machine.

[0028] This utility model provides a top ventilation structure for a baby bottle cleaner. By utilizing the top cover, water vapor is cooled, resulting in condensation on the top cover. The condensation falls into the collection chamber and then flows back into the ventilation hole. This not only prevents condensation from being generated outside the machine casing but also collects the condensation.

[0029] Furthermore, as a preferred embodiment of this solution and not a limitation thereof, the flow-collecting cavity 12 includes a bottom surface 121 and an inclined surface 122 that gradually slopes from the top surface 11 toward the bottom surface 121. The inclined surface 122 can effectively guide condensate to flow quickly toward the bottom surface 121 of the flow-collecting cavity, accelerating the collection and discharge of condensate and preventing it from stagnating in the upper part of the flow-collecting cavity.

[0030] Furthermore, as a preferred embodiment of this solution and not a limitation, the flow-gathering cavity 12 is provided with a first splash guard 14 and a second splash guard 15. The first splash guard 14 is located on the left and right sides of the vent hole 13 in the lateral direction, and the second splash guard 15 is located on the front and rear sides of the vent hole 13 in the longitudinal direction. When condensate flows back into the vent hole, it may be sprayed out due to the impact of water vapor. The first splash guard 14 and the second splash guard 15 form the first protective barrier to prevent splashing outside the casing.

[0031] Furthermore, as a preferred embodiment of this solution and not a limitation, the flow-gathering cavity 12 is also provided with a third splash guard 16 and a fourth splash guard 17. The third splash guard 16 is located on the left and right sides laterally of the first splash guard 14, and the fourth splash guard 17 is located on the front and rear longitudinal sides of the second splash guard 15. The third splash guard 16 and the fourth splash guard 17 are located further outward, forming a second protective barrier, expanding the splash protection range, intercepting condensate water that may bypass the first baffle, and further reducing the risk of water splashing outside the casing.

[0032] Furthermore, as a preferred embodiment of this solution and not a limitation, the length of the third splash guard 16 is greater than the length of the first splash guard 14, and the length of the fourth splash guard 17 is greater than the length of the second splash guard 15. The outer third and fourth splash guards are longer, have a wider coverage area, and can provide a more effective blocking effect.

[0033] Furthermore, as a preferred embodiment of this solution and not a limitation, the third splash guard 16 and the fourth splash guard 17 are located on the upper side of the inclined surface 122, and the first splash guard 14 and the second splash guard 15 are located on the lower side of the inclined surface 122 or on the bottom surface 121. Positioning the third and fourth splash guards on the upper side of the inclined surface 122 (closer to the top surface 11) provides a higher position and helps intercept splashed water; this staggered arrangement forms a multi-layered splash protection system.

[0034] Furthermore, as a preferred embodiment of this solution and not a limitation, a first turning gap 18 is provided between the first splash guard 14 and the second splash guard 15, and a second turning gap 19 is provided between the third splash guard 16 and the fourth splash guard 17. The top cover 2 is provided with a first turning baffle 22 corresponding to the outer side of the first turning gap 18, and a second turning baffle 23 corresponding to the outer side of the second turning gap 19. This creates a tortuous channel in the exhaust path. This forces water vapor to change direction multiple times during exhaust, increasing the residence time of steam in the exhaust chamber, which helps the steam condense into water and drip back into the convergence chamber. Furthermore, this circuitous path more effectively prevents tiny water droplets that may rise with the airflow from directly exiting the exhaust hole.

[0035] Furthermore, as a preferred embodiment of this solution and not a limitation, the flow-gathering cavity 12 is provided with a connecting post 4, and the top cover 2 is provided with a handle 5. The handle 5 is connected to the connecting post 4 by screws. By connecting the handle 5 and the connecting post 4 with screws, the top cover 2 is reliably and securely fixed on the flow-gathering cavity 12. At the same time, the structure is simple and convenient for users to install and remove the top cover using the handle 5, for example, for cleaning and maintenance.

[0036] Furthermore, as a preferred embodiment of this solution and not a limitation, the exhaust port 21 is located on the periphery of the top cover 2, and a diffusion channel 6 communicating with the exhaust port 21 exists between the periphery of the top cover 2 and the periphery of the converging cavity 12. By placing the exhaust port 21 on the periphery of the top cover and communicating with the exhaust cavity 3 through the diffusion channel 6, the direction of the discharged steam flow changes from vertically upward (or centrally concentrated) to horizontally diffused in all directions. This design effectively reduces the airflow velocity and concentration near the exhaust port, preventing high-temperature steam from directly spraying onto users or surrounding objects, while also helping the steam to spread more evenly and cool quickly.

[0037] The above description is only a preferred embodiment of this application and is not intended to limit the scope of implementation of this application. Any other embodiments whose principles and basic structures are the same as or similar to those of this application are within the protection scope of this application.

Claims

1. A breathable structure at the top of a baby bottle washing machine, characterized in that: include The housing (1) includes a top surface (11), a flow-gathering cavity (12) recessed on the top surface (11), and a vent (13) penetrating the flow-gathering cavity (12); A top cover (2) is used to cover the flow-collecting cavity (12) so that condensate drips into the flow-collecting cavity (12); An exhaust chamber (3) is formed between the housing (1) and the top cover (2) through which the vent (13) is connected, and the top cover (2) is provided with an exhaust hole (21) through which the exhaust chamber (3) is connected.

2. The top ventilation structure of a baby bottle washing machine according to claim 1, characterized in that: The flow-gathering cavity (12) includes a bottom surface (121) and an inclined surface (122) that gradually slopes from the top surface (11) toward the bottom surface (121).

3. The top ventilation structure of a baby bottle washing machine according to claim 2, characterized in that: The flow-gathering cavity (12) is provided with a first splash guard (14) and a second splash guard (15). The first splash guard (14) is located on the left and right sides of the vent (13) in the horizontal direction, and the second splash guard (15) is located on the front and rear sides of the vent (13) in the vertical direction.

4. The top ventilation structure of a baby bottle washing machine according to claim 3, characterized in that: The flow-gathering cavity (12) is also provided with a third splash guard (16) and a fourth splash guard (17). The third splash guard (16) is located on the left and right sides of the first splash guard (14) in the horizontal direction, and the fourth splash guard (17) is located on the front and rear sides of the second splash guard (15) in the vertical direction.

5. The top ventilation structure of a baby bottle washing machine according to claim 4, characterized in that: The length of the third splash guard (16) is greater than the length of the first splash guard (14), and the length of the fourth splash guard (17) is greater than the length of the second splash guard (15).

6. The top ventilation structure of a baby bottle washing machine according to claim 4, characterized in that: The third splash guard (16) and the fourth splash guard (17) are located on the upper side of the inclined surface (122), and the first splash guard (14) and the second splash guard (15) are located on the lower side of the inclined surface (122) or on the bottom surface (121).

7. The top ventilation structure of a baby bottle washing machine according to claim 4, characterized in that: A first turning gap (18) is provided between the first splash guard (14) and the second splash guard (15), and a second turning gap (19) is provided between the third splash guard (16) and the fourth splash guard (17). The top cover (2) is provided with a first turning baffle (22) corresponding to the outside of the first turning gap (18) and a second turning baffle (23) corresponding to the outside of the second turning gap (19).

8. The top ventilation structure of a baby bottle washing machine according to claim 1, characterized in that: The flow-gathering cavity (12) is provided with a connecting post (4), and the top cover (2) is provided with a handle (5). The handle (5) is connected to the connecting post (4) by screws.

9. The top ventilation structure of a baby bottle washing machine according to claim 1, characterized in that: The exhaust port (21) is located on the periphery of the top cover (2), and there is a diffusion channel (6) between the periphery of the top cover (2) and the periphery of the flow-gathering cavity (12) that communicates with the exhaust port (21).