ironing machine
By incorporating rectifiers and filters within the iron, the problem of excessive noise during clothing absorption has been solved, achieving both noise reduction and improved suction performance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG SHAOXING SUPOR DOMESTIC ELECTRICAL APPLIANCE CO LTD
- Filing Date
- 2025-07-09
- Publication Date
- 2026-06-30
AI Technical Summary
Existing irons are noisy when they pick up clothes, which affects the user experience.
The ironing machine is equipped with a rectifier, a filter assembly, and a suction assembly. The rectifier is located between the air inlets of the filter assembly and the suction assembly. The rectifier rectifies the airflow, and the filter assembly filters the air. The machine uses tiny pores to reflect and dissipate heat to reduce noise.
It effectively reduces gas flow noise, improves suction performance, extends the service life of the iron, and ensures internal cleanliness.
Smart Images

Figure CN224431067U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of household appliance technology, and more particularly to an ironing machine. Background Technology
[0002] An iron is a household appliance used for ironing clothes. It can absorb and iron clothes while they are hanging.
[0003] In related technologies, an ironing machine is equipped with a suction component. When the suction component is running, it draws air from the ironing panel of the ironing machine to make the clothes fit the ironing panel and facilitate ironing.
[0004] However, irons are quite noisy when they are holding clothes in the steamer. Utility Model Content
[0005] This application provides an ironing machine to solve the problem of excessive noise when existing ironing machines pick up clothes.
[0006] In a first aspect, embodiments of this application provide an ironing machine, comprising:
[0007] The housing has a receiving cavity inside;
[0008] The rectifier is housed within the receiving cavity;
[0009] A filter assembly is disposed within the receiving cavity;
[0010] The suction component is disposed within the receiving cavity, and the filter assembly is located between the rectifier and the air inlet of the suction component. The filter assembly is used to filter the gas entering the air inlet after passing through the rectifier.
[0011] The rectifier is configured to guide the gas entering the containment chamber to the filter assembly under the suction force of the suction component.
[0012] Thus, the rectifier, filter assembly, and suction assembly are all housed within the housing's accommodating cavity, with the filter assembly positioned between the air inlets of the rectifier and suction assembly. During suction operation, external air is drawn into the accommodating cavity and directed towards the rectifier. The rectifier guides and streamlines the airflow, ensuring a smoother flow to the filter assembly and reducing noise. As the air passes through the filter assembly, impurities are filtered out. Furthermore, the filter assembly, typically with numerous micropores for filtration, allows sound waves accompanying the air to collide with these micropores, resulting in reflection or heat dissipation and canceling out sound energy, further reducing noise. This effectively addresses the issue of excessive noise in existing ironing machines when absorbing clothing.
[0013] In one possible implementation, the ironing machine provided in this application embodiment further includes an air guide rib, which is disposed in the receiving cavity, and an ironing panel is disposed on the housing. The air guide rib is located between the ironing panel and the rectifier.
[0014] The air guide ribs are configured to guide the gas entering the containment cavity through the ironing panel to the rectifier.
[0015] In this way, the gas flow can be preliminarily guided by the air guide ribs before the gas flows into the rectifier hole, thus optimizing the stability and directionality of the gas.
[0016] In one possible implementation, the ironing machine provided in this application embodiment has a filter assembly including a support frame and a filter element. The support frame is provided with mounting holes that correspond to the air inlet. The filter element is disposed in the mounting holes and is used to filter the gas that enters the air inlet after passing through the rectifier.
[0017] In this way, the support frame can provide stable support for the installation of the filter element. The filter element is set between the rectifier and the air inlet, avoiding the situation where some areas are over-filtered and some areas are under-filtered due to airflow turbulence, so that the filtration of the entire filter element is more balanced.
[0018] In one possible implementation, the ironing machine provided in this application embodiment has a filter element that is at least one of filter cotton and filter screen.
[0019] In this way, different types of filter materials can be selected according to different filtration needs, or filter cotton and filter screen can be used in combination.
[0020] In one possible implementation, the ironing machine provided in this application embodiment further includes a flow guide in the filter assembly. The flow guide is disposed in the mounting hole and is used to guide the gas filtered by the filter to the air inlet.
[0021] In this way, the airflow entering the mounting hole can be further divided and guided by the air guide, so that the airflow is more evenly distributed in the air inlet area, making the air intake of the entire filter assembly more stable and uniform.
[0022] In one possible implementation, the volume of the guide component of the ironing machine provided in this application embodiment is greater than or equal to 1% of the volume of the support frame and less than or equal to 90% of the volume of the support frame.
[0023] This allows the gas to pass smoothly through the mounting hole and ensures the guiding effect of the guide component.
[0024] In one possible implementation, the ironing machine provided in this application embodiment includes at least two guide frames as the guide component, with a gap between adjacent guide frames, and the guide frames are symmetrically arranged in the mounting holes.
[0025] Thus, the symmetrically and spaced guide frames can effectively guide the flow path of the gas, reduce the formation of eddies and turbulence, and make the pressure distribution of the gas more symmetrical and balanced.
[0026] In one possible implementation, the ironing machine provided in this application embodiment has a guide frame including a plurality of intersecting guide ribs, the guide ribs being connected to the inner wall of the mounting holes.
[0027] In this way, the cross-connected guide ribs can form a grid structure, which can effectively enhance the overall strength and rigidity of the guide frame.
[0028] In one possible implementation, the ironing machine provided in this application embodiment includes a suction component comprising a fan blade and a drive component, wherein the drive component is connected to the fan blade and drives the fan blade to rotate.
[0029] The flow guide includes a flow guide ring and multiple flow guide ribs. One end of the flow guide rib is connected to the flow guide ring, and the other end of the flow guide rib is connected to the inner wall of the mounting hole. The flow guide ribs are arranged sequentially at intervals around the outer periphery of the flow guide ring. The flow guide ribs are used to guide the filtered gas to the fan blades.
[0030] This ensures that the gas can reach the fan blades more smoothly, while reducing noise and vibration caused by turbulence and reducing the energy required for the fan blades to generate suction.
[0031] In one possible implementation, the ironing machine provided in this application embodiment has an inlet / outlet hole on the housing, and a support frame is inserted into the housing through the inlet / outlet hole, with part of the support frame located outside the receiving cavity.
[0032] This allows the support frame to be inserted into the receiving cavity through the inlet and outlet holes, making disassembly and assembly easy and improving the assembly efficiency of the filter assembly.
[0033] In one possible implementation, the ironing machine provided in this application embodiment has one end of the support frame located outside the receiving cavity, and the other end of the support frame having a guide portion for guiding the support frame into the inlet / outlet hole.
[0034] Thus, by providing a guide, the support frame can be more easily aligned with the inlet and outlet holes, making it easier and faster to install the support frame into the receiving cavity.
[0035] In one possible implementation, the ironing machine provided in this application embodiment has an arc-shaped guide section.
[0036] This provides a smooth guide path for the guide section, making the relative positioning of the support frame and the inlet / outlet hole smoother and reducing the possibility of jamming or blockage between them.
[0037] In one possible implementation, the ironing machine provided in this application embodiment further includes a sealing element in the filter assembly. The sealing element is disposed on the support frame and is used to seal the gap between the inlet / outlet hole and the support frame.
[0038] In this way, the seal can effectively block these gaps, ensuring that all airflow entering the component must pass through the filter, thereby improving the filter's ability to intercept impurities, particulate matter, etc., and ensuring the quality of filtration.
[0039] In one possible implementation, the ironing machine provided in this application embodiment has at least one clearance notch on the support frame, and the clearance notch corresponds to the wiring channel or water pipe on the housing.
[0040] A boiler and a water tank are installed inside the cavity. The boiler is located between the suction unit and the ironing panel, and the water tank is connected to the boiler through a water pipe to supply water to the boiler.
[0041] In this way, by avoiding gaps, space is provided for wiring channels or water pipes, allowing the power supply lines and water supply lines inside the ironing machine to pass through the support frame.
[0042] In one possible implementation, the ironing machine provided in this application embodiment has at least two clearance notches, and the at least two clearance notches are respectively located on opposite sides of the support frame.
[0043] This allows lines to pass through the support frame from different directions, improving the flexibility and adaptability of cabling. Attached Figure Description
[0044] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.
[0045] Figure 1 This is a schematic diagram of the ironing machine provided in an embodiment of this application;
[0046] Figure 2 for Figure 1 A partial structural diagram of a medium-sized ironing machine;
[0047] Figure 3 for Figure 1 Internal structure diagram of a medium-sized ironing machine;
[0048] Figure 4 for Figure 1 A magnified view of a section at point A in the middle;
[0049] Figure 5 for Figure 3 Schematic diagram of the middle support frame Figure 1 ;
[0050] Figure 6 for Figure 5 Another structural schematic diagram of the central support frame;
[0051] Figure 7 for Figure 6 Schematic diagram of the BB direction of the central support frame;
[0052] Figure 8 for Figure 3 Schematic diagram of the middle support frame Figure 2 ;
[0053] Figure 9 for Figure 8 A schematic diagram showing the connection between the central support frame and the suction component.
[0054] Explanation of reference numerals in the attached figures:
[0055] 100 - Housing; 110 - Receiving cavity; 120 - Ironing panel; 130 - Inlet / outlet hole; 140 - Vent hole;
[0056] 200-Rectifier;
[0057] 300 - Filter assembly; 310 - Support frame; 311 - Mounting hole; 312 - Guide section; 313 - Clearance notch; 320 - Flow guide; 321 - Guide frame; 322 - Flow guide ring; 323 - Flow guide rib; 330 - Seal;
[0058] 400 - Suction component; 410 - Air inlet; 420 - Fan blade; 430 - Drive component;
[0059] 500-Air guide rib.
[0060] The accompanying drawings illustrate specific embodiments of this application, which will be described in more detail below. These drawings and descriptions are not intended to limit the scope of the concept in any way, but rather to illustrate the concept of this application to those skilled in the art through reference to particular embodiments. Detailed Implementation
[0061] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model. In the absence of conflict, the following embodiments and features can be combined with each other.
[0062] In related technologies, an ironing machine has a housing, an ironing panel, and a suction component installed inside the housing. When the suction component is running, it draws gas from the ironing panel of the ironing machine. The gas flows through the inside of the housing and enters the air inlet of the suction component, thereby forming an adsorption force on the ironing panel. Under the action of the adsorption force, the clothes adhere to the ironing panel, making it easy to iron.
[0063] However, the air flow from the ironing panel to the suction unit is quite turbulent, and the iron is noisy when it picks up clothes.
[0064] To overcome the shortcomings of existing technologies, this application provides an ironing machine in which a rectifier, a filter assembly, and a suction assembly are all disposed within the housing cavity, with the filter assembly located between the air inlets of the rectifier and the suction assembly. When the suction assembly is running, external air is drawn into the housing cavity and directed towards the rectifier. The rectifier guides and straightens the airflow, allowing it to flow more smoothly towards the filter assembly, thus reducing noise. As the air flows through the filter assembly, impurities are filtered, and because the filter assembly typically has numerous micropores to achieve its filtering effect, the sound waves accompanying the air collide with these micropores, reflecting or dissipating heat, and canceling out the sound wave energy, further reducing noise. This solves the problem of excessive noise in existing ironing machines when absorbing clothing.
[0065] The present invention will now be described in detail with reference to the accompanying drawings, so that those skilled in the art can have a clearer and more detailed understanding of the present invention.
[0066] To facilitate understanding, the application scenarios of the embodiments of this application will be described first.
[0067] The term "clothing" to be ironed by the ironing machine should be interpreted broadly, including but not limited to clothing, trousers, and other items for wearing, as well as fabrics such as curtains, sheets, and duvet covers. This application does not specifically limit this, and will be referred to as "clothing" below without further specific examples.
[0068] Reference Figures 1 to 3 As shown, this application embodiment provides an ironing machine, including:
[0069] The housing 100 has a receiving cavity 110 inside;
[0070] The rectifier 200 is disposed within the receiving cavity 110;
[0071] The filter assembly 300 is disposed within the receiving cavity 110;
[0072] The suction component 400 is disposed in the receiving cavity 110, and the filter assembly 300 is located between the rectifier 200 and the air inlet 410 of the suction component 400. The filter assembly 300 is used to filter the gas that enters the air inlet 410 through the rectifier 200.
[0073] The rectifier 200 is configured to guide the gas entering the receiving cavity 110 to the filter assembly 300 under the suction force of the suction member 400.
[0074] The housing 100 forms a receiving cavity 110 to provide installation space for the rectifier 200, the filter assembly 300, the suction assembly 400, and other components of the iron.
[0075] An ironing panel 120 is provided on the housing 100. The ironing panel 120 has a through hole communicating with the receiving cavity 110, and the air inlet 410 of the suction member 400 faces the ironing panel 120. This allows the suction member 400 to draw gas from the outside into the receiving cavity 110 through the through hole on the ironing panel 120, and the gas passes through the rectifier 200 and the filter assembly 300 in sequence before entering the suction member 400. An exhaust hole 140 is also provided on the housing 100 corresponding to the air outlet side of the suction member 400, so that the suction member 400 can exhaust air through the exhaust hole 140.
[0076] The rectifier 200 is located between the ironing panel 120 and the air inlet 410 of the suction component 400. The outer side wall of the rectifier 200 is connected to the inner side wall of the housing 100, and multiple rectifier holes are provided on the rectifier 200. So when the suction component 400 draws gas from the ironing panel 120 into the receiving cavity 110, the gas will pass through the rectifier holes on the rectifier 200 and then flow to the filter assembly 300.
[0077] The flow direction and flow rate of fluids such as air can be guided, controlled, or redistributed through the rectifier holes on the rectifier 200, thereby changing the flow path of the gas. As a result, when the gas passes through the rectifier holes, the flow direction of the gas will be consistent with the extension direction of the rectifier holes, making it more orderly and smooth. This reduces the degree of turbulence in the gas flow and thus reduces the noise of the gas flow.
[0078] When the gas passes through the filter assembly 300, the gas can be filtered by the filter assembly 300 to prevent impurities such as lint and fiber debris from entering the suction unit 400 and other parts inside the ironing machine with the gas. This ensures the cleanliness of the ironing machine, reduces the damage to the machine caused by the accumulation of impurities, and extends the service life of the ironing machine.
[0079] Meanwhile, the filter assembly 300, positioned between the rectifier 200 and the suction assembly 400, can guide the gas to accurately enter the air inlet 410, making the gas flow more orderly. This allows the suction assembly 400 to draw in the gas more efficiently, increasing the gas velocity and flow rate, thereby improving the overall suction performance of the ironing machine.
[0080] Furthermore, since the filter element 300 typically has tiny pores, gas can pass through it while impurities in the gas are intercepted. As the gas passes through the filter element 300, the sound wave energy of the gas collides with the tiny pores, and is then reflected or dissipated by the pores. The sound wave energy cancels each other out during reflection and dissipation, further reducing gas noise.
[0081] Thus, the rectifier 200, filter assembly 300, and suction assembly 400 are all disposed within the receiving cavity 110 of the housing 100, with the filter assembly 300 located between the rectifier 200 and the air inlet 410 of the suction assembly 400. In this way, when the suction assembly 400 is operating, it draws outside air into the receiving cavity 110 and directs the airflow towards the rectifier 200. The rectifier 200 rectifies the airflow, guiding and streamlining its direction, allowing it to flow more smoothly towards the filter assembly 300, thus reducing air noise. As the air flows through the filter assembly 300, it is filtered, intercepting impurities. Furthermore, because the filter assembly 300 typically has numerous micropores to achieve its filtering effect, when the air passes through it, the accompanying sound waves collide with these micropores, reflecting or dissipating heat, and canceling out the sound wave energy, further reducing noise. This solves the problem of excessive noise in existing ironing machines when absorbing clothing.
[0082] In some embodiments, refer to Figure 2 and Figure 3 As shown, the ironing machine also includes an air guide rib 500, which is disposed in the receiving cavity 110. An ironing panel 120 is disposed on the housing 100, and the air guide rib 500 is located between the ironing panel 120 and the rectifier 200.
[0083] The air guide rib 500 is configured to guide the gas entering the receiving cavity 110 through the ironing panel 120 to the rectifier 200.
[0084] By arranging multiple air guide ribs 500 at intervals on the inner wall of the housing 100, and positioning the air guide ribs 500 between the ironing panel 120 and the rectifier 200, the air flow direction can be preliminarily guided by the air guide ribs 500 before the air flows into the rectifier hole, thereby optimizing the stability and directionality of the air and reducing the degree of air turbulence, thus making the airflow of the rectifier 200 more stable.
[0085] It should be noted that the protrusion height of the air guide rib 500 relative to the inner wall of the housing 100 can be determined according to the space size of the accommodating cavity 110 and the installation requirements of the components inside the accommodating cavity 110. Specifically, the protrusion height of the air guide rib 500 can be set to abut and cooperate with the components installed inside the accommodating cavity 110 so that the air guide rib 500 can effectively guide the gas inside the housing 100, and the airflow and noise reduction effect is good. This application does not limit this.
[0086] In practice, the air guide rib 500 can be set inside the housing 100 near the ironing panel 120 so that the air can be guided by the air guide rib 500 as soon as possible after entering the housing 100, ensuring smooth air flow.
[0087] In some embodiments, refer to Figures 3 to 9 As shown, the filter assembly 300 includes a support frame 310 and a filter element. The support frame 310 is provided with a mounting hole 311, which corresponds to the air inlet 410. The filter element is disposed in the mounting hole 311 and is used to filter the gas that enters the air inlet 410 through the rectifier 200.
[0088] The support frame 310 has mounting holes 311, which provide stable support for the installation of the filter element and facilitate its fixation. The mounting holes 311 correspond to the air inlet 410 of the suction component 400, allowing gas to pass directly through the mounting holes 311 and the filter element within them, making gas filtration and flow smoother.
[0089] By placing the filter element between the rectifier 200 and the air inlet 410, the filter element is placed in a rectified airflow environment, which avoids the situation where some areas are over-filtered and some areas are under-filtered due to airflow turbulence, and makes the filtration of the entire filter element more balanced.
[0090] In practice, the filter element is at least one of filter cotton and filter screen.
[0091] It's understandable that filter cotton is relatively fluffy with many pores, which makes its filtration accuracy higher. On the other hand, filter mesh is generally grid-like and has higher structural strength. Although its filtration accuracy is lower than that of filter cotton, it has a longer service life and can be reused.
[0092] Therefore, different types of filter materials can be selected according to different filtration needs, or filter cotton and filter screen can be used in combination. This application does not limit this.
[0093] In some embodiments, refer to Figures 3 to 9 As shown, the filter assembly 300 also includes a flow guide 320, which is disposed in the mounting hole 311 and is used to guide the gas filtered by the filter to the air inlet 410.
[0094] The airflow guide 320 can further divide and guide the airflow entering the mounting hole 311, making the airflow more evenly distributed in the air inlet 410 area, and making the air intake of the entire filter assembly 300 more stable and uniform.
[0095] Furthermore, during installation, the filter element can be positioned on the side of the guide element 320 facing the rectifier 200, and the filter element can be made to abut against the guide element 320. This allows the guide element 320 to divide and guide the airflow filtered by the filter element, ensuring the uniformity and smoothness of the airflow. In addition, the guide element 320 can be used to support and block the filter element, preventing the filter element from being sucked into the air inlet 410.
[0096] In some embodiments, the volume of the guide 320 is greater than or equal to 1% of the volume of the support frame 310 and less than or equal to 90% of the volume of the support frame 310.
[0097] It is understandable that the total volume of the guide component 320 occupies 1%-90% of the volume of the support frame 310. When the total volume of the guide component 320 is greater than or equal to 1% of the volume of the support frame 310, the volume of the guide component 320 can be smaller, thereby forming a hole structure with a larger diameter in the mounting hole 311, so that the gas can pass through the mounting hole 311 smoothly. When the total volume of the guide component 320 is less than or equal to 90% of the volume of the support frame 310, the volume of the guide component 320 is larger, which ensures that the guide component 320 can effectively divide the mounting hole 311 into multiple small holes, so that the gas can be guided more fully by the guide component 320, thus ensuring the guiding effect of the guide component 320.
[0098] In some embodiments, refer to Figures 3 to 7 As shown, the flow guide 320 includes at least two guide frames 321, with a gap between adjacent guide frames 321, and the guide frames 321 are symmetrically arranged in the mounting holes 311.
[0099] It is understandable that the symmetrically and spaced guide frames 321 can effectively guide the flow path of the gas, reduce the formation of eddies and turbulence, thereby improving the flow efficiency of the fluid, and make the pressure distribution of the gas more symmetrical and balanced, so as to avoid the local pressure of the gas flowing through the guide members being too high or too low.
[0100] Specifically, refer to Figures 3 to 7 As shown, the guide frame 321 includes a plurality of intersecting guide ribs, which are connected to the inner wall of the mounting hole 311.
[0101] The cross-connected guide ribs can form a grid structure, and the guide ribs are connected to the inner wall of the mounting hole 311, which can effectively enhance the overall strength and rigidity of the guide frame 321 and provide better support and stability.
[0102] The grid-like guide ribs can precisely guide the gas flow, reduce the generation of turbulence and eddies, and optimize the gas flow path, thereby reducing the vibration and noise caused by the gas flowing through the guide ribs.
[0103] Furthermore, in some embodiments, reference is made to Figure 3 , Figure 8 and Figure 9 As shown, the suction component 400 includes a fan blade 420 and a drive component 430. The drive component 430 is connected to the fan blade 420 and drives the fan blade 420 to rotate.
[0104] The flow guide 320 includes a flow guide ring 322 and a plurality of flow guide ribs 323. One end of the flow guide rib 323 is connected to the flow guide ring 322, and the other end of the flow guide rib 323 is connected to the inner wall of the mounting hole 311. The flow guide ribs 323 are arranged sequentially at intervals around the outer periphery of the flow guide ring 322. The flow guide ribs 323 are used to guide the filtered gas to the fan blade 420.
[0105] The driving component 430 of the suction component 400 drives the fan blade 420 to rotate. The fan blade 420 specifically corresponds to the air inlet 410 of the suction component 400, thereby generating suction force at the air inlet 410 through the rotation of the fan blade 420. A guide ring 322 is provided corresponding to the fan blade 420. The diameter of the mounting hole 311 can be greater than or equal to the outer diameter of the fan blade 420, while the outer diameter of the guide ring 322 can be less than or equal to the outer diameter of the fan blade 420 and is coaxial with the fan blade 420 to ensure the guiding effect of the guide ring 322. Guide ribs 323 are sequentially spaced around the outer side of the guide ring 322 and the mounting hole 311 to ensure the stability of the position of the guide ring 322 and further provide the guiding effect. By combining the design of the guide ring 322 and the guide rib 323, the gas can be ensured to flow along the preset path, the gas guiding process can be optimized, and the gas can reach the fan blade 420 more smoothly. At the same time, the optimized gas flow path can reduce noise and vibration caused by turbulence and reduce the energy required for the fan blade 420 to form suction force, making it more energy-efficient and noise-reducing.
[0106] Furthermore, in some embodiments, reference is made to Figures 2 to 4 As shown, the housing 100 is provided with an inlet hole 130, and the support frame 310 is inserted into the housing 100 through the inlet hole 130, with part of the support frame 310 located outside the receiving cavity 110.
[0107] By opening an inlet / outlet hole 130 on the housing 100, the support frame 310 can be inserted into the receiving cavity 110 through the inlet / outlet hole 130, which makes disassembly and assembly easy and improves the assembly efficiency of the filter assembly 300.
[0108] Furthermore, when the support frame 310 is inserted into the receiving cavity 110, a portion of the support frame 310 is located outside the receiving cavity 110, thereby forming an operating part. By applying force to the operating part, the support frame 310 can be easily removed from the receiving cavity 110 through the inlet / outlet hole 130, further improving the disassembly efficiency of the filter assembly 300.
[0109] Furthermore, refer to Figures 4 to 9 As shown, one end of the support frame 310 is located outside the receiving cavity 110, and the other end of the support frame 310 has a guide portion 312, which is used to guide the support frame 310 into the inlet / outlet hole 130.
[0110] It is understandable that by providing the guide portion 312, the support frame 310 can be more easily aligned with the inlet / outlet hole 130 under the guidance of the guide portion 312, so that the support frame 310 can be quickly and easily installed in the receiving cavity 110.
[0111] In practice, the guide part 312 is an arc-shaped part.
[0112] The guide portion 312 formed by the arc-shaped portion can provide a smooth guiding path for the guide portion 312, helping the support frame 310 to automatically align with the correct position and direction when entering the inlet / outlet hole 130, so that the relative positioning of the support frame 310 and the inlet / outlet hole 130 is smoother and more fluid, reducing the possibility of jamming or blockage between the two.
[0113] Furthermore, referring to Figure 3 and Figure 4 As shown, the filter assembly 300 also includes a seal 330, which is disposed on the support frame 310 and is used to seal the gap between the inlet / outlet port 130 and the support frame 310.
[0114] If there is a gap between the inlet / outlet port 130 and the support frame 310, some unfiltered airflow may bypass the filter element and pass directly through these gaps. The seal 330 can effectively block these gaps, ensuring that all airflow entering the component must pass through the filter element, thereby improving the interception effect of the filter component 300 on impurities, particulate matter, etc., and ensuring the quality of filtration. In specific implementations, the seal 330 can be a rubber sealing ring.
[0115] In some embodiments, reference is made to Figures 5 to 9 As shown, the support frame 310 has at least one clearance notch 313, which corresponds to the wiring channel or water pipe on the housing 100.
[0116] A boiler and a water tank are installed inside the receiving cavity 110. The boiler is located between the suction unit 400 and the ironing panel 120. The water tank is connected to the boiler through a water pipe to supply water to the boiler.
[0117] In this way, by avoiding the gap 313, space can be provided for the wiring channel or water pipe, so that the power supply line and water supply line in the ironing machine can pass through the support frame 310 without obstruction, thereby optimizing the use of internal space and making the internal wiring layout of the ironing machine more simplified.
[0118] A boiler is installed between the suction unit 400 and the ironing panel 120. The boiler is connected to a water tank installed on the lower base of the housing 100 through a water supply pipe, so that the water tank can transport the water inside to the boiler through the water supply pipe, and the boiler heats the water to form steam for ironing.
[0119] The suction component 400 and the boiler are connected to a power source via a power supply line. Under the power supply, the suction component 400 forms an adsorption force, which heats the boiler.
[0120] Among them, reference Figures 5 to 9 As shown, at least two clearance gaps 313 are provided, and the at least two clearance gaps 313 are located on opposite sides of the support frame 310.
[0121] Clearance notches 313 are provided on opposite sides of the support frame 310, allowing lines or conduits to pass through the support frame 310 from different directions, improving the flexibility and adaptability of wiring. Furthermore, this allows for the simultaneous accommodation of multiple different lines or conduits to meet the wiring needs of the ironing machine.
[0122] It should be noted that the terms "one embodiment," "embodiment," "exemplary embodiment," "some embodiments," etc., mentioned in the specification indicate that the described embodiment may include a specific feature, structure, or characteristic, but not every embodiment necessarily includes that specific feature, structure, or characteristic. Furthermore, such phrases do not necessarily refer to the same embodiment. Moreover, when a specific feature, structure, or characteristic is described in connection with an embodiment, implementing such a feature, structure, or characteristic in conjunction with other embodiments, whether explicitly described or not, is within the knowledge scope of those skilled in the art.
[0123] Generally speaking, terms should be understood at least in part by their use in context. For example, at least in part by context, the term "one or more" as used in the text can be used to describe any feature, structure, or characteristic of the singular meaning, or a combination of features, structures, or characteristics of the plural meaning. Similarly, at least in part by context, terms such as "a" or "the" can also be understood to convey either singular or plural usage.
[0124] It should be readily understood that the terms “on,” “above,” and “on top of” in this application should be interpreted in the broadest possible sense, such that “on” means not only “directly on something” but also “on something” with an intermediate feature or layer therebetween, and that “above” or “on top of” means not only “on something” but also “on something” without an intermediate feature or layer therebetween (i.e., directly on something).
[0125] Furthermore, for ease of explanation, spatially relative terms such as "below," "below," "under," "above," and "above" may be used to describe the relationship of one element or feature relative to other elements or features as shown in the figures. Spatially relative terms are intended to encompass different orientations of the device in use or operation other than those shown in the figures. The device may have other orientations (rotated 90° or in other orientations), and the spatially relative descriptive terms used herein may be interpreted accordingly.
[0126] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of this utility model.
Claims
1. An ironing machine, characterized in that, include: The housing (100) has a receiving cavity (110) inside. A rectifier (200) is disposed within the receiving cavity (110); A filter assembly (300) is disposed within the receiving cavity (110); A suction component (400) is disposed within the receiving cavity (110), and a filter assembly (300) is located between the rectifier (200) and the air inlet (410) of the suction component (400). The filter assembly (300) is used to filter the gas entering the air inlet (410) through the rectifier (200). The rectifier (200) is configured to guide the gas entering the containment cavity (110) to the filter assembly (300) under the suction force of the suction member (400).
2. The ironing machine according to claim 1, characterized in that, It also includes an air guide rib (500), which is disposed in the receiving cavity (110). An ironing panel (120) is disposed on the housing (100), and the air guide rib (500) is located between the ironing panel (120) and the rectifier (200). The air guide rib (500) is configured to guide the gas entering the receiving cavity (110) through the ironing panel (120) to the rectifier (200).
3. The ironing machine according to claim 2, characterized in that, The filter assembly (300) includes a support frame (310) and a filter element. The support frame (310) is provided with a mounting hole (311), which corresponds to the air inlet (410). The filter element is disposed in the mounting hole (311) and is used to filter the gas that enters the air inlet (410) through the rectifier (200).
4. The ironing machine according to claim 3, characterized in that, The filter element is at least one of filter cotton and filter screen.
5. The ironing machine according to claim 3, characterized in that, The filter assembly (300) further includes a flow guide (320) disposed within the mounting hole (311) and used to guide the gas filtered by the filter to the air inlet (410).
6. The ironing machine according to claim 5, characterized in that, The volume of the guide (320) is greater than or equal to 1% of the volume of the support frame (310) and less than or equal to 90% of the volume of the support frame (310).
7. The ironing machine according to claim 5, characterized in that, The flow guide (320) includes at least two guide frames (321), with a gap between adjacent two guide frames (321), and the guide frames (321) are symmetrically arranged in the mounting holes (311).
8. The ironing machine according to claim 7, characterized in that, The guide frame (321) includes a plurality of intersecting guide ribs, which are connected to the inner wall of the mounting hole (311).
9. The ironing machine according to claim 5, characterized in that, The suction component (400) includes a fan blade (420) and a drive component (430), wherein the drive component (430) is connected to the fan blade (420) and drives the fan blade (420) to rotate; The flow guide (320) includes a flow guide ring (322) and a plurality of flow guide ribs (323). One end of the flow guide rib (323) is connected to the flow guide ring (322), and the other end of the flow guide rib (323) is connected to the inner wall of the mounting hole (311). The flow guide ribs (323) are arranged sequentially at intervals around the outer periphery of the flow guide ring (322). The flow guide ribs (323) are used to guide the filtered gas to the fan blade (420).
10. The ironing machine according to any one of claims 3-9, characterized in that, The housing (100) is provided with an inlet / outlet hole (130), and the support frame (310) is inserted into the housing (100) through the inlet / outlet hole (130). Part of the support frame (310) is located outside the receiving cavity (110).
11. The ironing machine according to claim 10, characterized in that, One end of the support frame (310) is located outside the receiving cavity (110), and the other end of the support frame (310) has a guide portion (312) for guiding the support frame (310) into the inlet / outlet hole (130).
12. The ironing machine according to claim 11, characterized in that, The guide part (312) is an arc-shaped part.
13. The ironing machine according to claim 10, characterized in that, The filter assembly (300) further includes a seal (330) disposed on the support frame (310) and the seal (330) is used to seal the gap between the inlet / outlet (130) and the support frame (310).
14. The ironing machine according to any one of claims 3-9, characterized in that, The support frame (310) has at least one clearance notch (313), which corresponds to a wiring channel or water pipe on the housing (100); A boiler and a water tank are provided in the receiving cavity (110). The boiler is located between the suction member (400) and the ironing panel (120). The water tank is connected to the boiler through the water pipe to supply water to the boiler.
15. The ironing machine according to claim 14, characterized in that, At least two clearance gaps (313) are provided, and the at least two clearance gaps (313) are located on opposite sides of the support frame (310).