A sterilizing cabinet for reducing noise

By designing a chimney-like elongated inner liner structure and aerodynamic mechanism in the disinfection cabinet, the noise problem of the disinfection cabinet fan has been solved, achieving quiet operation and energy-saving effect.

CN224370260UActive Publication Date: 2026-06-19NINGBO MEIGAO KITCHENWARE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NINGBO MEIGAO KITCHENWARE CO LTD
Filing Date
2025-06-09
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing disinfection cabinets generate significant noise during operation due to the fan, which negatively impacts the user experience.

Method used

The design adopts a longitudinal cross-sectional area larger than the transverse cross-sectional area of ​​the inner liner, forming a narrow and elongated cavity similar to a chimney. An aerodynamic mechanism replaces the fan, with the first air inlet and air intake channel located at the bottom of the inner liner, and the air outlet assembly located at the top of the inner liner, forming natural convection, enhancing the rising speed of hot air, eliminating noise and reducing power consumption.

Benefits of technology

It effectively reduces noise interference from the disinfection cabinet, increases natural convection speed, saves energy and is environmentally friendly, eliminates fan noise, and enhances the user experience.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The present disclosure relates to the technical field of disinfection cabinets, and particularly relates to a disinfection cabinet for reducing noise, a disinfection cabinet for reducing noise, which comprises a shell assembly, an inner container arranged in the interior of the shell assembly and used for containing articles to be disinfected, the longitudinal cross-sectional area of the inner container being greater than the transverse cross-sectional area thereof, an air power mechanism for air flow circulation in the inner container, the air power mechanism being composed of a first air inlet, an air inlet channel, a heating assembly, an air outlet assembly and a plurality of air outlets, wherein the first air inlet is arranged at the bottom of the shell assembly, the air inlet channel is arranged in a cavity between the shell assembly and the inner container and located at the lower part of the inner container, the air inlet channel comprises air flow channels which are respectively communicated with the first air inlet and the bottom of the inner container, the air outlet assembly is arranged at the upper part of the inner container, and the plurality of air outlets are arranged at the top of the shell assembly. The present application can eliminate the noise generated by the operation of the fan from the root cause and avoid the interference of the noise to users.
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Description

Technical Field

[0001] This disclosure relates to the field of disinfection cabinet technology, and in particular to a disinfection cabinet for reducing noise. Background Technology

[0002] With the increasing demand for infant and toddler health care in modern families, sterilization technology for maternal and infant products has gradually become a focus of attention. A maternal and infant sterilization cabinet is a sterilization device specifically designed for infants and postpartum women. It is mainly used for sterilization and disinfection, effectively killing bacteria, viruses, fungi, and other microorganisms, ensuring the hygiene and safety of products for infants and pregnant women.

[0003] Most disinfection cabinets are equipped with fans, which run when the cabinet is in operation. However, the fans often produce considerable noise during operation, which can be quite bothersome for users who are sensitive to noise. Utility Model Content

[0004] In view of the shortcomings or problems existing in the prior art, this disclosure provides a disinfection cabinet for reducing noise. The disinfection cabinet for reducing noise has a simple structure and can operate quietly.

[0005] The technical solution adopted by this disclosure to solve the above-mentioned technical problem is: a disinfection cabinet for reducing noise, comprising:

[0006] Housing components;

[0007] The inner liner, located inside the outer shell assembly, is used to hold the items to be sterilized. The longitudinal cross-sectional area of ​​the inner liner is greater than its transverse cross-sectional area.

[0008] An aerodynamic mechanism for airflow within the inner liner, comprising a first air inlet, an air inlet channel, an air outlet assembly, a heating assembly, and several exhaust ports, wherein the heating assembly is disposed on the air inlet channel;

[0009] The first air inlet is located at the bottom of the housing assembly;

[0010] The air inlet channel is located in the cavity between the outer shell assembly and the inner liner, and is located at the lower part of the inner liner. The air inlet channel includes an airflow channel, which is connected to the first air inlet and the bottom of the inner liner respectively.

[0011] The air outlet assembly is located at the upper part of the inner liner;

[0012] The plurality of exhaust ports are located on the top of the housing assembly.

[0013] In a preferred embodiment, the heating component includes a first heating component, the air inlet channel includes a first air inlet channel, the airflow channel includes a first airflow channel, the first heating component is disposed in the first airflow channel, the first air inlet channel includes a first housing, the first airflow channel is disposed in the inner cavity of the first housing, the bottom of the first housing is provided with a first air inlet, and the bottom of the inner liner is provided with a second air inlet.

[0014] In a preferred embodiment, the second air inlet includes a first hollow structure and a second hollow structure. The first hollow structure is disposed opposite to the first air inlet, and the second hollow structure is disposed on the side of the first air inlet. The area ratio of the first hollow structure to the second hollow structure is less than 1:4.

[0015] In a preferred embodiment, the first heating component is disposed at the bottom of the first box body, a gap is provided between the first heating component and the inner liner, and a graphene layer is disposed on the side of the first heating component facing the inner liner.

[0016] In a preferred embodiment, the heating assembly further includes a second heating assembly, the air inlet channel includes a second air inlet channel, the airflow channel further includes a second airflow channel, the second heating assembly is disposed in the second airflow channel, the second air inlet channel includes a second housing, the second airflow channel is disposed in the inner cavity of the second housing, a third air inlet is disposed at the bottom of the second housing, and a fourth air inlet is disposed at the bottom of the inner liner.

[0017] In a preferred embodiment, the fourth air inlet includes a third hollow structure and a fourth hollow structure. The third hollow structure is disposed directly opposite the third air inlet, and the fourth hollow structure is disposed on the side of the third air inlet. The area ratio of the third hollow structure to the fourth hollow structure is less than 1:4.

[0018] In a preferred embodiment, the second heating component is disposed at the bottom of the second box body, a gap is provided between the second heating component and the inner liner, and a graphene layer is disposed on the side of the second heating component facing the inner liner.

[0019] In a preferred embodiment, the first air inlet is located in the middle of the bottom of the housing assembly, and the first air inlet and the third air inlet are respectively located on both sides of the first air inlet.

[0020] In a preferred embodiment, the inner liner includes a top wall, two first side walls, a bottom wall, and a second side wall. The top wall and the bottom wall are arranged opposite to each other, the two first side walls are arranged opposite to each other, and the second side wall is located between the two first side walls. The air outlet assembly includes a first air outlet and a second air outlet. The first air outlet is disposed on the second side wall, and the height of the first air outlet is greater than one-third of the height of the second side wall. The second air outlet is disposed on the top wall.

[0021] In a preferred embodiment, the first air outlet is a hollow structure arranged along the width direction of the second side wall, and the second air outlet includes at least three air outlet structures arranged along the width direction of the inner liner.

[0022] In a preferred embodiment, a cover plate assembly is provided on the top of the housing assembly. The cover plate assembly includes a square annular frame and a first cover plate. The first cover plate covers the upper part of the square annular frame, and a gap is provided between the first cover plate and the square annular frame. A plurality of vents are provided on at least two sidewalls of the square annular frame.

[0023] Compared with existing products, this application sets the longitudinal cross-sectional area of ​​the inner liner to be larger than the transverse cross-sectional area, making the inner liner form a long and narrow cavity similar to a "chimney". This significantly increases the height of the hot air rising path. At the same time, the first air inlet and air inlet channel are located at the bottom of the inner liner, and the air outlet is located at the top of the inner liner. This lengthens the height distance between the airflow initiation point and the airflow outlet, directly improving the natural convection speed and accelerating the efficiency of hot air exhaust. The aerodynamic mechanism in this application replaces the fan in the prior art, which can eliminate the noise of fan operation at the source and avoid noise interference to users. The chimney effect does not require additional electrical energy to drive the airflow, which can significantly reduce the power consumption of the whole machine and make it more energy-saving and environmentally friendly. Attached Figure Description

[0024] The present application will be described in further detail below with reference to the accompanying drawings and preferred embodiments. However, those skilled in the art will understand that these drawings are drawn only for the purpose of explaining the preferred embodiments and therefore should not be construed as limiting the scope of the present application. Furthermore, unless specifically indicated, the drawings are only schematic representations of the composition or structure of the described objects and may contain exaggerated depictions, and the drawings are not necessarily drawn to scale.

[0025] Figure 1 This is a structural schematic diagram of a disinfection cabinet for reducing noise.

[0026] Figure 2 This is one of the structural schematic diagrams of the inner liner disclosed herein;

[0027] Figure 3 This is a cross-sectional view of a disinfection cabinet for reducing noise disclosed herein;

[0028] Figure 4 This is the second schematic diagram of the inner liner structure disclosed herein;

[0029] Figure 5 This is a cross-sectional view of the inner liner of this publication;

[0030] Figure 6 This is a schematic diagram of the ring-shaped frame structure disclosed herein.

[0031] Explanation of reference numerals in the attached figures:

[0032] 1. Outer shell assembly; 2. Inner liner; 3. Cover plate assembly; 5. First air inlet; 6. First air intake section; 7. First hollow structure; 8. Second hollow structure; 9. Third air intake section; 10. Third hollow structure; 11. Fourth hollow structure; 12. Square ring frame; 13. Exhaust port; 14. First airflow channel; 15. Second airflow channel; 16. First heating component; 17. Second heating component; 19. First air outlet section; 20. Second air outlet section; 21. Top wall; 22. First side wall; 23. Second side wall. Detailed Implementation

[0033] To enable those skilled in the art to better understand the technical solutions of this disclosure, the following detailed, clear, and complete description of this disclosure is provided in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of this disclosure and are not intended to limit it.

[0034] Those skilled in the art should understand that in the disclosure of this utility model, the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., 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, the above terms should not be construed as a limitation of this utility model.

[0035] Please refer to Figure 1 , Figure 2 and Figure 6As shown, this application provides a disinfection cabinet for reducing noise, comprising an outer shell assembly 1 and an inner liner 2. The outer shell assembly includes a shell and a door panel. The inner liner 2 is disposed inside the outer shell assembly 1 and is used to accommodate items to be disinfected. The longitudinal cross-sectional area of ​​the inner liner 2 is larger than its transverse cross-sectional area. It also includes an aerodynamic mechanism for airflow in the inner liner 2. The aerodynamic mechanism consists of a first air inlet 5, an air inlet channel, an air outlet assembly, a heating assembly, and several exhaust ports 13. The heating assembly is disposed on the air inlet channel. The first air inlet 5 is disposed at the bottom of the outer shell assembly 1. The air inlet channel is disposed in the cavity between the outer shell assembly 1 and the inner liner 2, and is located at the lower part of the inner liner 2. The air inlet channel includes an airflow channel. The heating assembly is used to heat the gas in the airflow channel. The airflow channel is connected to the first air inlet 5 and the bottom of the inner liner 2 respectively. The air outlet assembly is disposed at the upper part of the inner liner 2. Several exhaust ports 13 are disposed at the top of the outer shell assembly 1. This application sets the longitudinal cross-sectional area of ​​the inner liner 2 to be larger than its transverse cross-sectional area, making the inner liner 2 form a long and narrow cavity similar to a "chimney," significantly increasing the height of the hot air rising path. At the same time, the first air inlet 5 and the air inlet channel are located at the bottom of the inner liner 2, and the air outlet component is located at the top of the inner liner 2, lengthening the height distance between the airflow starting point and the airflow outlet. The hot air in the inner liner 2 rises due to its lower density, and the cold air at the bottom is continuously replenished through the first air inlet 5, forming a vertical airflow circulation that does not require external power, improving the natural convection speed and accelerating the efficiency of hot air discharge. The aerodynamic mechanism in this application replaces the fan in the prior art. The disinfection cabinet does not have a fan, which can eliminate the noise of fan operation at the source and avoid noise interference to users. The chimney effect does not require additional electricity to drive the airflow, which can significantly reduce the power consumption of the whole machine and make it more energy-saving and environmentally friendly.

[0036] Please refer to the following: Figures 2-5As shown, the heating assembly includes a first heating assembly 16, the air inlet channel includes a first air inlet channel, and the airflow channel includes a first airflow channel 14. The first heating assembly 16 is disposed in the first airflow channel 14. The first air inlet channel includes a first housing, and the first airflow channel 14 is disposed in the inner cavity of the first housing. A first air inlet 6 is disposed at the bottom of the first housing, and a second air inlet is disposed at the bottom of the inner liner 2. Specifically, the second air inlet includes a first hollow structure 7 and a second hollow structure 8. The first hollow structure 7 is disposed directly opposite the first air inlet 6, and the second hollow structure 8 is disposed on the side of the first air inlet 6. The area ratio of the first hollow structure 7 to the second hollow structure 8 is less than 1:4. More specifically, the inner liner 2 includes a top wall 21, two first side walls 22, a bottom wall, and a second side wall 23. The second side wall 23 is located on the back of the inner liner 2. The top wall 21 and the bottom wall are disposed opposite each other, the two first side walls 22 are disposed opposite each other, and the second side wall 23 is located between the two first side walls 22. Both the first hollow structure 7 and the second hollow structure 8 are located on the bottom wall. The first hollow structure 7 consists of several spaced circular holes extending from the outer side of the bottom wall towards the second side wall 23. The second hollow structure 8 consists of several spaced elongated holes extending from the outer side of the bottom wall towards the second side wall 23. The first hollow structure 7 faces the first air inlet 6, forming a vertical directional airflow that rises rapidly under the chimney effect. The second hollow structure 8, through side air intake, balances the local negative pressure generated by the high-speed airflow of the first hollow structure 7, preventing airflow turbulence due to pressure imbalance and ensuring that hot air is evenly diffused to the dead corners at the edges of the inner liner 2. The area ratio of the first hollow structure 7 to the second hollow structure 8 is less than 1:4. By limiting the air intake of the first hollow structure 7 to increase the flow rate, and by ensuring sufficient air intake for the second air inlet through the second hollow structure 8, the disinfection cabinet achieves high-flow-rate core disinfection and large-volume coverage.

[0037] Furthermore, the first heating component 16 is disposed at the bottom of the first housing. Gaps are provided between the first heating component 16 and the inner liner 2, and between the first heating component 16 and the bottom of the first housing. A graphene layer is disposed on the side of the first heating component 16 facing the inner liner 2. Specifically, the first heating component 16 is a heating tube, used to heat the gas entering the first airflow channel 14. The heated gas enters the inner liner 2 through the first perforated structure 7 and the second perforated structure 8. By placing the first heating component 16 at the bottom of the first housing, the hot gas flows from bottom to top, forming a chimney effect and enhancing the airflow in the inner liner 2. Gaps are provided between the first heating component 16 and the inner liner 2, and between the first heating component 16 and the bottom of the first housing. These gaps allow the gas in the first airflow channel 14 to fully contact the first heating component 16, improving heating efficiency. More specifically, the first heating component 16 is a plate-like structure with arc-shaped surfaces on both sides. The arc-shaped surfaces guide the airflow, preventing obstruction and accelerating airflow. The graphene layer can accelerate thermal radiation and further improve thermal conversion efficiency.

[0038] Furthermore, the heating assembly also includes a second heating assembly 17, the air inlet channel also includes a second air inlet channel, and the airflow channel also includes a second airflow channel 15. The second heating assembly 17 is disposed in the second airflow channel 15. The second air inlet channel includes a second housing, and the second airflow channel 15 is disposed in the inner cavity of the second housing. A third air inlet 9 is disposed at the bottom of the second housing, and a fourth air inlet is disposed at the bottom of the inner liner 2. Specifically, the fourth air inlet includes a third hollow structure 10 and a fourth hollow structure 11. The third hollow structure 10 is disposed directly opposite the third air inlet 9, and the fourth hollow structure 11 is disposed on the side of the third air inlet 9. The area ratio of the third hollow structure 10 to the fourth hollow structure 11 is less than 1:4. Both the third hollow structure 10 and the fourth hollow structure 11 are disposed on the bottom wall of the inner liner 2. The third hollow structure 10 consists of several spaced circular holes that extend from the outer side of the bottom wall toward the second side wall 23. The fourth perforated structure 11 consists of several elongated holes spaced apart, extending from the outer side of the bottom wall towards the second side wall 23. The third perforated structure 10 faces the third air inlet 9, forming a vertically directional airflow that rises rapidly under the chimney effect. The fourth perforated structure 11, through side air intake, balances the local negative pressure generated by the high-speed airflow of the third perforated structure 10, preventing airflow turbulence due to pressure imbalance and ensuring that hot air is evenly diffused to the dead corners at the edges of the inner liner 2. The area ratio of the third perforated structure 10 to the fourth perforated structure 11 is less than 1:4. By limiting the air intake of the third perforated structure 10 to increase the flow rate, and by ensuring sufficient air intake for the fourth air inlet through the fourth perforated structure 11, the disinfection cabinet achieves high-flow-rate core disinfection and large-volume coverage.

[0039] Preferably, the second heating component 17 is disposed at the bottom of the second housing, with gaps between the second heating component 17 and the inner liner 2, and between the second heating component 17 and the bottom of the second housing. A graphene layer is disposed on the side of the second heating component 17 facing the inner liner 2. The structure of the second heating component 17 is the same as that of the first heating component 16, and will not be described in detail here.

[0040] The first air inlet 5 is located in the middle of the bottom of the outer casing assembly 1, and the first air inlet 6 and the third air inlet 9 are respectively located on both sides of the first air inlet 5. Outside air enters the outer casing assembly 1 through the first air inlet 5, and then splits into two paths, entering the first airflow channel 14 and the second airflow channel 15 through the first air inlet 6 and the third air inlet 9 respectively. Then, it enters the inner liner 2 through the second air inlet and the fourth air inlet respectively.

[0041] like Figure 4 As shown, in one embodiment of this disclosure, the air outlet assembly includes a first air outlet 19 and a second air outlet 20. The first air outlet 19 is disposed on the second side wall 23 of the inner liner 2, and the height of the first air outlet 19 is greater than one-third of the height of the second side wall 23. The second air outlet 20 is disposed on the top wall 21. Specifically, the first air outlet 19 is a hollow structure arranged along the width direction of the second side wall 23, and the second air outlet 20 includes four air outlet structures arranged along the width direction of the inner liner 2. Specifically, the air outlet structure consists of three spaced through holes. The area of ​​the first air outlet 19 is larger than that of the second air outlet 20. The first air outlet 19 is the main air outlet channel. The height of the first air outlet 19 is greater than one-third of the height of the second side wall 23. Setting the height of the first air outlet 19 higher can lengthen the airflow path in the inner liner 2. In addition, the second air outlet 20 can further exhaust the hot air accumulated at the top and prevent the hot air from stagnating. The first air outlet 19 and the second air outlet 20 work together to enhance the chimney effect.

[0042] Please refer to Figure 5 and Figure 6As shown in the figure, a cover plate assembly 3 is provided at the top of the outer shell assembly 1. Specifically, the cover plate assembly 3 includes a square annular frame 12 and a first cover plate. The first cover plate covers the upper part of the square annular frame 12, and there is a gap between the first cover plate and the square annular frame 12. A plurality of exhaust ports 13 are provided on three side frames of the square annular frame 12. Specifically, the square annular frame 12 has a "return" - shaped structure, which includes four side frames. Two side frames are respectively located above the first side wall 22 of the inner container 2, one side frame is located above the second side wall 23 of the inner container 2, and another side frame is located above the disinfection cabinet door panel. The exhaust ports 13 are provided on the two side frames above the first side wall 22 and the side frame above the second side wall 23. The hot air in the inner container 2 enters the space between the inner container 2 and the outer shell assembly 1 through the first air outlet part 19 and the second air outlet part 20, and then is discharged through the exhaust ports 13. A gap is provided between the first cover plate and the square annular frame 12 to facilitate exhaust.

[0043] The above has introduced this application in detail. Specific examples are used in this article to elaborate on the principle and implementation mode of this application. The description of the above embodiments is only used to help understand this application and its core idea. It should be pointed out that for those of ordinary skill in the art, without departing from the principle of this application, several improvements and modifications can be made to this application, and these improvements and modifications also fall within the protection scope of the claims of this application.

Claims

1. A sterilizer for reducing noise, characterized by, include: Housing assembly (1); The inner liner (2) is located inside the outer shell assembly (1) and is used to contain items to be disinfected. The longitudinal cross-sectional area of ​​the inner liner (2) is greater than its transverse cross-sectional area. An aerodynamic mechanism for airflow in the inner liner (2) is provided, comprising a first air inlet (5), an air inlet channel, an air outlet assembly, a heating assembly, and several exhaust ports (13), wherein the heating assembly is provided on the air inlet channel; The first air inlet (5) is located at the bottom of the outer casing assembly (1); The air inlet channel is located in the cavity between the outer shell assembly (1) and the inner liner (2), and is located at the lower part of the inner liner (2). The air inlet channel includes an airflow channel, which is connected to the first air inlet (5) and the bottom of the inner liner (2) respectively. The air outlet assembly is located at the upper part of the inner liner (2); The plurality of exhaust ports (13) are disposed on the top of the housing assembly (1).

2. The disinfection cabinet for reducing noise according to claim 1, characterized in that, The heating component includes a first heating component (16), the air inlet channel includes a first air inlet channel, the airflow channel includes a first airflow channel (14), the first heating component (16) is disposed in the first airflow channel (14), the first air inlet channel includes a first box body, the first airflow channel (14) is disposed in the inner cavity of the first box body, the bottom of the first box body is provided with a first air inlet (6), and the bottom of the inner liner (2) is provided with a second air inlet.

3. The disinfection cabinet for reducing noise according to claim 2, characterized in that, The second air inlet includes a first hollow structure (7) and a second hollow structure (8). The first hollow structure (7) is positioned opposite the first air inlet (6), and the second hollow structure (8) is positioned on the side of the first air inlet (6). The area ratio of the first hollow structure (7) to the second hollow structure (8) is less than 1:

4.

4. The disinfection cabinet for reducing noise according to claim 2, characterized in that, The first heating component (16) is located at the bottom of the first box body. A gap is provided between the first heating component (16) and the inner liner (2). A graphene layer is provided on the side of the first heating component (16) facing the inner liner (2).

5. The disinfection cabinet for reducing noise according to claim 2, characterized in that, The heating component further includes a second heating component (17), the air inlet channel further includes a second air inlet channel, the airflow channel further includes a second airflow channel (15), the second heating component (17) is disposed in the second airflow channel (15), the second air inlet channel includes a second box body, the second airflow channel (15) is disposed in the inner cavity of the second box body, the bottom of the second box body is provided with a third air inlet (9), and the bottom of the inner liner (2) is provided with a fourth air inlet.

6. The disinfection cabinet for reducing noise according to claim 5, characterized in that, The fourth air inlet includes a third hollow structure (10) and a fourth hollow structure (11). The third hollow structure (10) is positioned opposite the third air inlet (9), and the fourth hollow structure (11) is positioned on the side of the third air inlet (9). The area ratio of the third hollow structure (10) to the fourth hollow structure (11) is less than 1:

4.

7. The disinfection cabinet for reducing noise according to claim 5, characterized in that, The second heating component (17) is located at the bottom of the second box body. There is a gap between the second heating component (17) and the inner liner (2). A graphene layer is provided on the side of the second heating component (17) facing the inner liner (2).

8. The disinfection cabinet for reducing noise according to claim 2 or 5, characterized in that, The first air inlet (5) is located in the middle of the bottom of the outer casing assembly (1), and the first air inlet (6) and the third air inlet (9) are respectively located on both sides of the first air inlet (5).

9. The disinfection cabinet for reducing noise according to claim 1, characterized in that, The inner liner (2) includes a top wall (21), two first side walls (22), a bottom wall and a second side wall (23). The top wall (21) and the bottom wall are arranged opposite to each other, the two first side walls (22) are arranged opposite to each other, and the second side wall (23) is located between the two first side walls (22). The air outlet assembly includes a first air outlet (19) and a second air outlet (20). The first air outlet (19) is arranged on the second side wall (23), and the height of the first air outlet (19) is greater than one-third of the height of the second side wall (23). The second air outlet (20) is arranged on the top wall (21).

10. The disinfection cabinet for reducing noise according to claim 9, characterized in that, The first air outlet (19) is a hollow structure arranged along the width direction of the second side wall (23), and the second air outlet (20) includes at least three air outlet structures arranged along the width direction of the inner liner (2).