VACUUM STEAMER
A hand-held vacuum steamer with a front portion including a steam outlet at a first surface of a lower portion of the front portion and an air intake for a suction system at a second surface of an upper portion of the front portion, a steam generator for selectively generating steam and delivering steam to the steam outlet by way of a steam flow path, where the suction system includes a fan motor operatively connected with the power circuit for selectively driving a fan that creates an air flow path that fluidly connects the air intake to an air outlet by way of the air flow path, and where the air outlet is located on one or more side portions of the head proximate to the rear portion thereof, such that air is ejected laterally from the suction system during operation.
This application claims priority to and the benefit of Chinese Patent Application No. 2024119991921, filed Dec. 31, 2024 and entitled VACUUM STEAMER and also claims priority to and the benefit of Chinese Patent Application No. 2025114964015, filed Oct. 20, 2025 and entitled VACUUM STEAMER, the contents of which are incorporated herein by reference in their entireties.
TECHNICAL FIELDThe present application relates to steamers, and more particularly to electrically-powered hand-held steamers
BACKGROUNDSteamers can be hand-held electrically heated devices that receive water in a
reservoir and that heat and convert that water to gaseous steam within a boiler or steam generator on demand for application, e.g., to clothes, fabrics, and the like. Irons can produce steam, but are intended to be used horizontally and rely primarily on a heated metal soleplate in order to smooth fabrics or the like. Hand-held steamers, in contrast, are typically operated in an upright or vertical manner, such as to be used on articles such as hanging clothes, and may or may not be used in direct contact with articles to be heated during operation. During steaming operation, a flow of steam is expelled from such a steamer.
Portable hand-held steamers can be provided with an on-board water reservoir, in contrast the steam stations, which can have a steamer head connected to a large base station via a hose, and where the base station includes operative steam generation features, such as a boiler and the water reservoir.
SUMMARYAspects of the invention described herein are directed to hand-held steamers that are provided in a portable, all-in-one unit. The present invention introduces improved steamer operation by employing a suction function with an intake located near a steam output. The result is a counteracting suction force to that of expelled steam on an article to be steamed. The improved portable steamer further discharges air resulting from the suction feature laterally and away from a user, such as by vents provided in the sides of the rear portion of the steamer.
Aspects of the invention described herein are directed to hand-held steamers that are provided in a portable, all-in-one unit. The present invention introduces improved steamer operation by employing a suction function with an intake located near a steam output. The result is a counteracting suction force to that of expelled steam on an article to be steamed. The improved portable steamer further discharges air resulting from the suction feature laterally and away from a user, such as by vents provided in the sides of the rear portion of the steamer.
The present invention even further provides for a shrouded, air-moving fan that operatively causes air from the suction system to pass around and through the shroud of the fan before being caused to exit laterally via the side exits from an air flow path of the suction system. Also provided herein are embodiments in which one or more seals are utilized at various interfaces or joints between components so as to at least partially isolate a flow or compartment from at least another flow or compartment or to make a particular flow or compartment substantially fluid-tight at one or more joints or interfaces, e.g., to optimize operational aspects or extend a useful life of a steamer.
The result is a compact and portable hand-held steamer with operational advantages, such as a suction effect that offsets a proximate repulsion by the steam output, and that further improves air flow and a direction of air ejection from the steamer head during operation. A more convenient and more pleasant steaming operation and steamer ownership experience results.
According to a first embodiment of the present disclosure, a hand-held vacuum steamer is disclosed. According the first embodiment, the head-held vacuum steamer includes a housing including a base and a head that are connected with one another by a graspable handle. Still according to the first embodiment, the head includes a front portion, a rear portion, and one or more side portions, the front portion including a steam outlet at a first surface of a lower portion of the front portion and an air intake at a second surface of an upper portion of the front portion. The head-held vacuum steamer also includes a steam delivery system including an internal water reservoir that is fluidly connected to a steam generator provided within the housing by way of a water flow path including a water pump operatively connected with a power circuit for moving water along the water flow path from the internal water reservoir to the steam generator, the steam generator operatively connected with the power circuit for selectively generating steam and delivering steam to the steam outlet by way of a steam flow path. The hand-held vacuum steamer also includes a suction system including a fan motor operatively connected with the power circuit for selectively driving a fan that creates an air flow path that fluidly connects the air intake to an air outlet by way of the air flow path, where the air outlet is located on one or more side portions of the head proximate to the rear portion thereof, such that air is ejected laterally from the suction system during operation. Still according to the first embodiment, the water pump, the steam generator, and the fan motor are selectively operable by one or more controls for operating the vacuum steamer so as to deliver steam from the front portion of the head below a suction generated at the front portion of the head at the air intake.
According to a second embodiment of the present disclosure, a method of using a hand-held vacuum steamer is disclosed. According to the second embodiment, the method includes moving water along a water flow path from an internal water reservoir to a steam generator. The method also includes generating steam from the water using the steam generator. The method also includes delivering the generated steam to a steam outlet at a front portion of a steamer head by way of a steam flow path. The method also includes creating a suction at an air intake at an upper part of the front portion of the steamer head using an air flow path that fluidly connects the air intake to an air outlet using a fan motor driving a fan, where the air outlet is located on one or more side portions of the head such that air is ejected laterally from the head during operation. The final also includes positioning and/or moving the steamer head near an article to be steamed.
According to a third embodiment of the present disclosure a hand-held vacuum steamer is disclosed. According to the third embodiment, the head-held vacuum steamer includes a housing including an interior, a base, and a head, where the base and head are connected with one another by a graspable handle. The head includes a front portion, a rear portion, and one or more side portions, the front portion including a steam outlet at a first surface of a lower portion of the front portion and an air intake at a second surface of an upper portion of the front portion. Also according to the third embodiment, the head-held vacuum steamer includes a steam delivery system including an internal water reservoir that is fluidly connected to a steam generator provided within the housing by way of a water flow path including a water pump operatively connected with a power circuit for moving water along the water flow path from the internal water reservoir to the steam generator, the steam generator operatively connected with the power circuit for selectively generating steam and delivering steam to the steam outlet by way of a steam flow path. Also according to the third embodiment, the head-held vacuum steamer includes a suction system including a fan motor operatively connected with the power circuit for selectively driving a fan that creates an air flow path that fluidly connects the air intake to an air outlet by way of the air flow path, where the air outlet is located on one or more side portions of the head proximate to the rear portion thereof, such that air is ejected laterally from the suction system during operation. Also according to the third embodiment, the water pump, the steam generator, and the fan motor are selectively operable by one or more controls for operating the vacuum steamer so as to deliver steam from the front portion of the head below a suction generated at the front portion of the head at the air intake, and where at least one of the front portion, the rear portion, and the suction system is provided with a substantially water-tight seal at an interface with at least the interior of the housing to enhance isolation of the air flow path from the housing interior.
These and various other features and advantages will be apparent from a reading of the following detailed description.
The present invention will be further explained with reference to the appended Figures, wherein like structure is referred to by like numerals throughout the several views, and wherein:
Aspects of the invention described herein are directed to hand-held steamers that are preferably each provided as a portable, all-in-one unit.
With reference to
As shown in
In more detail, as shown in
The air flow path 48, as shown best in
Turning now to
The water flow path 44, which can preferably be composed of pre-pump section 44A and post-pump section 44B (collectively, water flow path 44), is shown best in
In preferable embodiments, once the water from the reservoir 34 follows the water flow path 44 and is converted to steam, the steam flow path 46 of the steam delivery system can begin. In other words, the water flow path 44 and the steam flow path 46 can form a single flow path circuit in various embodiments. In the steam chamber 42, as the water is preferably converted to gaseous steam, a flow of steam can be created, such that steam can flow out from the steam outlets 26 of the surface 24 at the front 22 of the head 12. Thus, during operation, such as selectively initiated by a user through controls 20, steam can be caused to exit the front 22 of the steamer 10, such as to apply the steam to an article, e.g., hanging clothes or the like. During operation, such as positioning and/or moving the steamer near the article to be steamed, at least some repulsive force can be exerted on the article to be steamed by the steam in various examples as it is being expelled from the front 22. The steaming repulsive force can be at least partially offset by a suction attractive force relative to the article.
The size of the outlets 26 of the front steam exit for steam can be configured to be larger or smaller in diameter, e.g., to provide higher or lower steam pressure. For example, the outlets 26 can be configured such that steam exit flow avoids undue steam being sucked into the air flow path 48. In various preferred embodiments, the air flow path 48 and the steam flow path 46 are substantially fluidically separate. Also as shown in the first embodiment, the outlets 26 are provided in generally horizontally extending channels or recessed grooves of the first surface 24 of the front 22 of the head 12. Optionally, the first surface 24 can be heated, such as by electrical resistive heating and/or by being heated by steam flowing therethrough and/or in contact therewith. The first surface 24 is therefore optionally a heated plate that can be configured to contact the article to be steamed and/or pressed.
As described above, a localized, negative-pressure, suction effect preferably results from the air flow path 48 having its intake 28 at the surface 25 of the front portion 22 of the steamer head 12. Also as shown, the air intake 28 (see, e.g.,
In preferable embodiments, the air and steam flow paths (48, 46) are also optimized to achieve optimal pressure (suction) for the steaming, e.g., of the garment or article. The flow paths and resulting flows, e.g., volume and speed of fluid flow, including volumetrics, can be further be optimized, e.g., for preferable motor assembly 60 aspects, such as nominal motor RPM, load, etc.
In preferable embodiments, e.g., steamer 10, steam is preferably provided or expelled from the steamer 10 at a higher pressure than the corresponding air suction or negative pressure as a negative pressure amplitude (or vacuum, e.g., in mmHg). A benefit of a greater force and quantity of steam output relative to air input is to promote the chances that a certain quantity of steam provided exceeds that steam that may be sucked into and removed by the air intake, and thus ensuring that enough steam remains in order to operatively smooth the article to be steamed. Therefore, preferably, steam flow is selected to be a higher flow than the corresponding air flow suction such that the steam flow reaches the article to be steamed even when suction is activated.
With reference to
Additional details of the first embodiment are also shown in
Similar to steamer 10, the hand-held vacuum steamer 110 is generally composed of a head 112, a handle 114, and a base 116, and includes an operative steam delivery system and related aspects and an operative suction system and related aspects. The head 112 of the steamer 110 is provided with air flow, water flow, and steam flow paths and features, as shown and described below. The head 112 can include a head housing 118 with a front portion 122, a rear portion 123, and side portions 130 for creating an enclosure. The front portion 122 of the housing 118 can include a first surface 124 which can comprise a plate (e.g., a metal plate), provided with steam outlet(s) (e.g., output openings) 126 sized and arranged according to various steaming aspects. The front portion 122 of the housing 118 also preferably includes, as shown, a second surface 125 provided with air intake slots 128. In various embodiments, the first and second surfaces 124 and 125, are both at the front portion 122, and can together form an operative front steaming surface. Optionally, the first surface 124 and the second surface 125 are substantially co-planar. At or proximate the rear portion 123 of the housing 118 are one or more air outlets 132, preferably near the one or more side portions 130 proximate the rear portion 123 of the housing 118. Optionally, the first surface 124 can be heated, such as by electrical resistive heating and/or by being heated by steam flowing therethrough and/or in contact therewith. The first surface 124 is therefore optionally a heated plate that can be configured to contact an article to be steamed and/or pressed.
As shown in
Also according to the second embodiment of steamer 110, controls 120 are provided, which can include and/or be coupled with a power circuit (not shown), can optionally include a power control, a temperature control, a steaming control, a water pump control, and/or any other suitable controls. The controls 120 preferably include two or more buttons are provided on the handle 114. As shown, a top button of controls 120 is configured to release steam on demand. In some configurations, a user can either briefly press or hold the top button of the controls 120 for an extended period. A brief press of the top button provides for on/off toggling of continuous steaming operation (until pressed again, etc.), and a press-and-hold action results in on-demand steaming until the button is released by the user. Various settings can be provided for operation of the steamer 110. For example, the first embodiment steamer 10 may provide for a single setting for suction, while the second embodiment steamer 110 can provide two or more options for suction level (e.g., in mmHg measured at the front 122). Steaming using steamer 110 preferably provides for consistent (single level) steaming, whereas suction can preferably be set to various levels and settings, such as off, low, or high. In various configurations and settings, the user can use the steamer 110 for steam only or can instead use a steam-plus-vacuum setting. Each of the settings can be configured for low, high, or any variation thereof. As shown, the top button of the controls 120 can allow for a sliding operation of the button. As shown, a slider switch is provided at controls 120 to select the suction level for operation in the second embodiment of the steamer 110. For example, sliding the button can change a setting from low, to high, to off. Other variations and combinations are also contemplated, and any described control aspects of controls 120 can be applied to the steamer 10 as applicable, and vice-versa.
Optionally integrally formed or formed of various separate components (e.g., of plastic or other materials), the base 116, positioned below the handle 114, preferably includes a reservoir 134 as shown in
In more detail, the steamer 110 can be provided with various fluid paths, including an air flow path 148 of a suction system, a steam flow path 146 of a steam delivery system, and a water flow path 144 of the steam delivery system. Each fluid or other path can comprise one or more sub-paths or path branches within a portion of the respective path. See, e.g.,
The air flow path 148, as shown best in
As shown, the steamer 110 can beneficially provide an alternative configuration that provides an alternative air flow chamber 149 configured for smooth, tapered, laminar flow of air passing internally through the air flow chamber 149 of the air flow path 148 during operation. The disclosed air flow chamber 149 minimizes sudden and sharp turns, such as ups or downs, in the air flow path 148, and provides gradual curvature for the air flowing therethrough. Improving effective laminar flow within the air flow chamber 149 can reduce various pressures during operation, and can thus reduce resulting sound and noise during operation (e.g., emitted from motor assembly 160). As a result of lower noise compared to existing configurations, disclosed embodiments provide for relatively higher power and higher suction per emitted sound. Thus, for a given sound level, a greater amount of motor speed and/or suction were able to be achieved.
The water flow path 144, which can preferably be composed of pre-pump section 144A and post-pump section 144B (collectively, water flow path 144), is shown best in
In preferable embodiments, once the water from the reservoir 134 follows the water flow path 144 and is converted to steam, the steam flow path 146 of the steam delivery system can begin. In other words, the water flow path 144 and the steam flow path 146 can form a single flow path circuit in various embodiments. In the boiler unit 151, as the water is preferably converted to gaseous steam, a flow of steam can be created, such that steam can flow out from the steam outlets 126 of the surface 124 at the front 122 of the head 112. Thus, during operation, such as selectively initiated by a user through controls 120, steam can be caused to exit the front 122 of the steamer 110, such as to apply the steam to hanging clothes or the like. During operation, some repulsive force can be exerted on the article to be steamed by the steam in various examples as it is being expelled from the front 122. The size of the outlets 126 of the front steam exit for steam can be configured to be larger or smaller in diameter, e.g., to provide higher or lower steam pressure. For example, the outlets 126 can be configured such that steam exit flow avoids undue steam being sucked into the air flow path 148. In various preferred embodiments, the air flow path 148 and the steam flow path 146 are fluidically separate.
The second embodiment of steamer 110 has an alternative front portion 122 configuration, as shown, among other variations. As shown in
In preferable embodiments, e.g., steamer 110, steam is preferably provided or expelled from the steamer 110 at a higher pressure than a magnitude of the corresponding air suction. A benefit of a greater force and quantity of steam output relative to air input is to promote the chances that a certain quantity of steam provided exceeds what is sucked into and removed by the air intake, and thus ensuring that enough steam remains in order to operatively smooth the article to be steamed. Therefore, preferably, steam flow is provided at a higher rate than the suction so an operative steam flow remains even when the suction function is activated.
As described above, a localized, negative-pressure, suction effect preferably results from the air flow path 148 having its intake 128 at the surface 125 of the front portion 122 of the steamer head 112. Also as shown, the air intake 128 (see, e.g.,
In preferable embodiments, the air and steam flow paths (148, 146) are optimized to achieve optimal pressure (suction) for the steaming, e.g., of the garment or article. The flow paths and resulting flows, e.g., volume and speed of fluid flow, including volumetrics, can be further be optimized, e.g., for preferable motor assembly 160 aspects, such as nominal motor RPM, load, etc.
In preferable embodiments, the air and steam flow paths (148, 146) are optimized to achieve optimal pressure (suction) for the steaming, e.g., of the garment or article. The flow paths and resulting flows, e.g., volume and speed of fluid flow, including volumetrics, can be further be optimized, e.g., for preferable motor assembly 160 aspects, such as nominal motor RPM, load, etc.
With reference to
Also as shown on steamer 110, and with particular reference to
As shown, a power source 210 can be provided, and a controller 212 can be connected to the power source 210. The controller 212, which can further comprise a power circuit, can include an operatively connected processor and a memory. The controller 212 can be operatively connected to a steam/water system 214 and an air/suction system 224.
The steam/water system 214 preferably comprises a steam generator 216, a water reservoir 218, a water pump 220, and a steam outlet 222. As shown, the steam outlet 222 can be operatively associated with an operative vacuum steamer surface 232. The air/suction system 224 preferably includes a shrouded fan 226, an air outlet 228, and an air intake 230. As shown, the air intake 230 can also be operatively associated with the operative vacuum steamer surface 232, optionally above, below, and/or proximate the steam outlet 222. As described herein, the operative vacuum steamer surface 232 can be used to apply steam to fabrics, such as clothes, textiles, or the like with a beneficial ease of use.
The steamer 310 is understood to be substantially similar to steamer 110 in particular, except as noted below. The steamer 310 is generally composed of a head 312, a handle 314, and a base 316, and includes an operative steam delivery system and related aspects and an operative suction system and related aspects described in various embodiments herein. The head 312 of the steamer 310 can be provided with air flow, water flow, and steam flow paths and features, as shown and described in other embodiments, herein. The head 312 can include a head housing 318 with a front portion 322, a rear portion 323 (associated with a rear plate 382), and side portions 330 for creating an enclosure. As shown in
The front portion 322 of the housing 318 can include a first surface 324 which can comprise a plate (e.g., a metal plate), provided with steam outlet(s) (e.g., output openings) 326 sized and arranged according to various steaming aspects. The front portion 322 of the housing 318 also preferably includes, as shown, a second surface 325 provided with air intake (slots) 328. In various embodiments, the first and second surfaces 324 and 325, are both at the front portion 322, and can together form an operative front steaming surface. Optionally, the first surface 324 and the second surface 325 are substantially co-planar. At or proximate the rear portion 323 of the housing 318 are one or more air outlets 332, similar to various other embodiments. Optionally, the first surface 324 can be heated, such as by electrical resistive heating and/or heat transfer from steam flowing therethrough and/or in contact therewith. The first surface 324 is therefore optionally a heated plate that can be configured to contact an article to be steamed and/or pressed.
A graspable handle 314 is shown, which can be similar to handle 114 described above, and which can define at least a part of and/or can at least partially enclose a lower housing interior 376. As in other embodiments described above, the steamer 310 can be provided with various fluid paths. The lower housing interior is preferably fluidly separate from any of the various fluid paths, including the air flow, water flow, and steam flow paths. The lower housing interior 376 can include one or more operative components, including various electrical and/or electronic components as discussed above and shown in, e.g.,
In order to keep certain components dry or to provide other advantageous effects, such as improved efficiency, the steamer 310 can beneficially include features to limit or prevent water from entering the lower housing interior 376 from the vacuum airflow, which may include generated steam. One or more additional substantially hermetic or substantially fluid-tight seals at various interfaces of the housing 318. For example, front and rear seals 378, 374, and seal (e.g., gasket) 370 are shown in
For example, at least one of the front portion 322, the rear portion 323, and the suction system can be provided with a substantially water-tight seal at an interface with at least the interior of the housing 372 to enhance isolation of the air flow path (and/or steam flow path) from the housing interior 372.
A smoothly tapered air flow housing 350 can define a substantially sealed air flow chamber 349 of a suction system provided within the housing 318. The air flow housing 350 preferably comprises an upper portion 366, which can be removably attachable at a circumferential channel or groove 368 of a lower portion 369 of the housing 350 in the steamer head 312. As shown in
Such air flow path (e.g., similar to path 148) can begin at the air intake 328, and air can be pulled through a passage behind the surface 325, and then can reach the motor assembly 360 (see, e.g., motor assembly 60 and fan assembly 61 of
The front seal 378 can be provided, optionally in a removable or replaceable manner, at or along a circumferential edge of a front plate support 377. The front seal 378 can be disposed at an interface between the front portion 322 and/or a plate portion 379 and the front plate support 377 and/or the steamer body 318. In this configuration, the front seal 378 preferably functions to inhibit the passage of air, water, and/or steam through the interface, thereby forming a substantially air-tight and water-tight joint at or near the front portion 322. The water-tight joint can, for example, separate the air flow path and the upper housing interior 372. The front seal 378 can be formed of an elastomeric material, gasket, O-ring, or other suitable sealing structure, and may be press-fit, adhesively bonded, threaded, or otherwise secured in place. Preferably, the rear seal 374 can be positioned at an interface between a rear support 380 and at least a portion of the steamer body 318, such as along a circumferential or perimeter region of the rear support 380, in order to provide a corresponding substantially air- and water-tight seal at or near the rear portion 323. The rear seal 374 can be formed of an elastomeric material, gasket, O-ring, or other suitable sealing structure, and may be press-fit, adhesively bonded, threaded, or otherwise secured in place. Each of the front and rear seals 378, 374 can act individually or in cooperation to prevent leakage of steam, air, or liquid through various parts of the housing 318, thereby enhancing device performance and user safety.
In operation, water/steam can potentially intrude over time into various non-operative portions of the steamer 310. Benefits of the front 378 and rear 374 seals can be to avoid fluid intrusion across an interface and into an upper housing interior 372 and/or into the lower housing interior 376, which may be open to one another or fluidly separate in various embodiments. Benefits of the seal 370 can include avoidance of water/steam intrusion into the upper housing interior 372 and/or providing a more efficient steaming operation through a less leaky air flow path within the air flow chamber 349.
By substantially and tightly sealing the chamber, the steamer 310 can maintain a pressure differential between the air flow chamber 349 and ambient atmosphere, and thus improve suction and overall steamer 310 performance. A substantially fluidically sealed configuration preferably prevents unintended leakage paths so that incoming air, liquid, or steam is drawn predominantly through the designated intake, thereby concentrating the flow and increasing intake velocity. Such sealing also improves efficiency of the motor assembly 360, as less energy is consumed compensating for leaks and more of the generated negative pressure is translated into useful suction at the air intake 328. In addition, such a sealed chamber can provide more stable and predictable operation, reducing turbulence and pressure fluctuations that may otherwise diminish cleaning or fluid-removal effectiveness.
Any of the seals or gaskets 370, 374, 378, 66, 68 can be an elastomeric (for example, rubber, silicone, nitrile, or fluorocarbon) O-ring or other suitable construction or shape. In some cases, the seals may instead be formed of a polymer such as PTFE or a fiber-reinforced or metallic gasket material, depending on the operating environment. The seals can be press-fit, threaded, or otherwise secured between adjacent portions in order to provide a tight seal at various interfaces.
The present invention has now been described with reference to several embodiments thereof. The foregoing detailed description and examples have been given for clarity of understanding only. No unnecessary limitations are to be understood therefrom. It will be apparent to those skilled in the art that many changes can be made in the embodiments described without departing from the scope of the invention. The implementations described above and other implementations are within the scope of the following claims.
Claims
1. A hand-held vacuum steamer, comprising:
- a housing comprising a base and a head that are connected with one another by a graspable handle;
- the head comprising a front portion, a rear portion, and one or more side portions, the front portion comprising a steam outlet at a first surface of a lower portion of the front portion and an air intake at a second surface of an upper portion of the front portion;
- a steam delivery system comprising an internal water reservoir that is fluidly connected to a steam generator provided within the housing by way of a water flow path including a water pump operatively connected with a power circuit for moving water along the water flow path from the internal water reservoir to the steam generator, the steam generator operatively connected with the power circuit for selectively generating steam and delivering steam to the steam outlet by way of a steam flow path; and
- a suction system comprising a fan motor operatively connected with the power circuit for selectively driving a fan that creates an air flow path that fluidly connects the air intake to an air outlet by way of the air flow path, wherein the air outlet is located on one or more side portions of the head proximate to the rear portion thereof, such that air is ejected laterally from the suction system during operation,
- wherein the water pump, the steam generator, and the fan motor are selectively operable by one or more controls for operating the vacuum steamer so as to deliver steam from the front portion of the head below a suction generated at the front portion of the head at the air intake.
2. The hand-held vacuum steamer of claim 1, wherein the one or more controls are located on the graspable handle portion, wherein the steam generator is positioned within the head, and wherein the water reservoir is positioned within the base.
3. The hand-held vacuum steamer of claim 1, further comprising a controller operatively connectable to a power source, wherein the controller is configured to operatively power the fan motor, the water pump, and a heating element of the steam generator.
4. The hand-held vacuum steamer of claim 1, wherein the air outlet comprises at least two air outlets comprising a first air outlet and a second air outlet, wherein the first air outlet is located at a first side portion of the head, and wherein the second air outlet is located at a second side portion of the head, opposite the first side portion.
5. The hand-held vacuum steamer of claim 1, wherein the first surface of the head comprises a heated metal plate.
6. The hand-held vacuum steamer of claim 1, wherein the first surface and the second surface are substantially co-planar.
7. The hand-held vacuum steamer of claim 1, wherein the steam outlet comprises a plurality of openings.
8. The hand-held vacuum steamer of claim 1, wherein at least one of the fan motor, the front portion, the rear portion, and the suction system is provided with a substantially water-tight seal.
9. The hand-held vacuum steamer of claim 1, further comprising a rear seal positioned at an interface between a rear support and at least a portion of the housing, wherein the rear seal is positioned along a circumferential or perimeter region of the rear support, and is configured to provide a corresponding substantially air- and water-tight seal at or near the rear portion.
10. The hand-held vacuum steamer of claim 1, wherein the air flow path and the steam flow path are fluidically separate.
11. The hand-held vacuum steamer of claim 1, wherein the steam delivery system is configured to produce steam to be applied to an article while the air intake provides suction to pull the article toward the front portion of the head, wherein the steam produced by the steam delivery system causes a repulsive force to be applied to the article, and wherein the suction system creates a suction force on the article, such that at least some of the repulsive force on the article is offset.
12. The hand-held vacuum steamer of claim 11, wherein the first surface of the head comprises a heated metal plate, and wherein the heated metal plate is configured to contact the article during operation.
13. The hand-held vacuum steamer of claim 1, wherein the air intake comprises a filter supported to the head.
14. The hand-held vacuum steamer of claim 1, further comprising a cleaning brush removably attachable to the base for storage, wherein the cleaning brush is configured to clean the filter of the head.
15. The hand-held vacuum steamer of claim 1, wherein the fan motor comprises a motor housing and one or more internal electrical or electronic parts, wherein the motor housing further comprises a motor seal configured to provide a water-tight seal to prevent water and/or steam from reaching the one or more internal electrical or electronic parts, and wherein the air flow path is configured to pass through at least a portion of the motor housing.
16. A method of using a hand-held vacuum steamer, comprising:
- moving water along a water flow path from an internal water reservoir to a steam generator,
- generating steam from the water using the steam generator;
- delivering the generated steam to a steam outlet at a front portion of a steamer head by way of a steam flow path;
- creating a suction at an air intake at an upper part of the front portion of the steamer head using an air flow path that fluidly connects the air intake to an air outlet using a fan motor driving a fan, wherein the air outlet is located on one or more side portions of the head such that air is ejected laterally from the head during operation; and
- positioning and/or moving the steamer head near an article to be steamed.
17. A hand-held vacuum steamer, comprising:
- a housing comprising an interior, a base, and a head, wherein the base and head are connected with one another by a graspable handle;
- the head comprising a front portion, a rear portion, and one or more side portions, the front portion comprising a steam outlet at a first surface of a lower portion of the front portion and an air intake at a second surface of an upper portion of the front portion;
- a steam delivery system comprising an internal water reservoir that is fluidly connected to a steam generator provided within the housing by way of a water flow path including a water pump operatively connected with a power circuit for moving water along the water flow path from the internal water reservoir to the steam generator, the steam generator operatively connected with the power circuit for selectively generating steam and delivering steam to the steam outlet by way of a steam flow path; and
- a suction system comprising a fan motor operatively connected with the power circuit for selectively driving a fan that creates an air flow path that fluidly connects the air intake to an air outlet by way of the air flow path, wherein the air outlet is located on one or more side portions of the head proximate to the rear portion thereof, such that air is ejected laterally from the suction system during operation,
- wherein the water pump, the steam generator, and the fan motor are selectively operable by one or more controls for operating the vacuum steamer so as to deliver steam from the front portion of the head below a suction generated at the front portion of the head at the air intake, and wherein at least one of the front portion, the rear portion, and the suction system is provided with a substantially water-tight seal at an interface with at least the interior of the housing to enhance isolation of the air flow path from the housing interior.
18. The hand-held vacuum steamer of claim 17, wherein the substantially water-tight seal comprises:
- i) a rear seal positioned at an interface between a rear support and at least a portion of the housing, wherein the rear seal is positioned along a circumferential or perimeter region of the rear support, and is configured to provide a corresponding substantially air- and water-tight seal at or near the rear portion and the interior of the housing,
- ii) a front seal positioned at an interface between the front portion and at least a portion of the housing, wherein the front seal is positioned along a circumferential or perimeter region of the front portion, and is configured to provide a corresponding substantially air- and water-tight seal at or near the front portion and the interior of the housing, and/or
- iii) an upper seal positioned at an interface between an upper portion and a lower portion of an air flow housing, wherein the upper seal is positioned along a groove of the lower portion of the air flow housing, and is configured to provide a corresponding substantially air- and water-tight seal at or near the upper portion and the interior of the housing.
19. The hand-held vacuum steamer of claim 17, wherein the substantially water-tight seal is configured to provide a substantially water-tight air-flow path that is fluidically isolated from the steam flow path.
20. The hand-held vacuum steamer of claim 19, wherein plural water-tight seals are provided.
Type: Application
Filed: Dec 5, 2025
Publication Date: Jul 2, 2026
Inventors: Firdaus Sameer Nandoliya (Verona, WI), Vignesh Manikandan Pirathaban (Madison, WI), Fang Guohong (Ningbo), Ma Dengliang (Ningbo)
Application Number: 19/410,668