The present invention relates to the field of steam generators for small steam appliances such as steam cleaners, steam mops, etc.
It is known to employ steam generators to convert liquid water into steam as part of the operation of a small steam appliance such as a consumer steam cleaner, steam mop, etc. A steam generator typically includes a heating element and surrounding structure that establishes a fluid flow path along which the water flows to be converted into steam by heat from the heating element. The resulting steam is provided via an outlet of the steam generator to a separate steam discharge component of the small appliance.
In a small steam appliance, steam may be discharged from a steam generator at a relatively narrow outlet from which it travels to a steam discharge component or other point of use in the appliance. During the conversion process, solid particles such as mineral salts may be formed due to the presence of minerals such as calcium and magnesium in the water. The salts are deposited within the steam generator and the deposits build up over time. Deposited material can be dislodged in the form of relatively large particles that can cause blockage at the outlet. In time, the blockage can increase to the point of reducing the effective operation of the appliance or rendering it completely unusable. Thus, the natural action of particle formation in a steam generator of an appliance may determine the length of the useful life of the appliance.
Disclosed is a steam generator capable of delivering good life expectancy by reducing such blockage at an outlet at which steam is discharged. The steam generator includes an inlet configured to receive a liquid (such as water); a heating element for converting the liquid into a vapor (such as steam), the vapor bearing particles formed by the converting of the liquid; an outlet in fluid communication with the inlet, the outlet configured to discharge filtered vapor and having a size on the order of larger ones of the particles; and a filter structure adjacent to the outlet to filter the larger particles out of the vapor to produce the filtered vapor for discharge from the outlet. By action of the filter structure, larger particles are prevented from reaching the outlet, reducing clogging and extending the usable lifetime of a small appliance containing the steam generator.
In some embodiments, the filter structure includes a set of spaced-apart members forming a screen substantially larger than an opening of the outlet. The members may be formed as posts or pillars extending perpendicularly in a planar passage through which the liquid and vapor flow. These posts or pillars may be integrally formed with a cover or other structural member of the steam generator, such as by molding or die casting. The spacings among the members may be set in relation to a diameter of the outlet to ensure that larger particles become trapped by the members while smaller particles can pass through the members and exit the outlet.
The foregoing and other objects, features and advantages will be apparent from the following description of particular embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of various embodiments of the invention.
It will be appreciated by those of ordinary skill in the art that the disclosure can be embodied in other specific forms without departing from the spirit or essential character thereof. The presently disclosed embodiments are therefore considered in all respects to be illustrative and not restrictive.
Generally, the filter structure 16 (also referred to as “filter” 16 herein) has an effective surface area across the flow path that is significantly larger than the opening of the outlet, so that the rate at which the filter 16 becomes clogged by filtered particles is much lower than the rate at which the outlet would become clogged in the absence of the filter. For example, the effective surface area of the filter may be five times the size of the outlet opening or greater. Specific examples are described below.
Although not shown in
The steam generator 20 includes an internal heating element (not shown in
As shown in
Also shown in
Also shown in
Further regarding the vanes 52, 62, they define points at which a direction of the fluid flow path changes abruptly (e.g., at openings in their ends). While serpentine paths are useful to increase heat transfer to the fluid, they can contribute to the build-up of deposits if their lengths are excessive. Thus, it is generally preferred that there be only a small number of direction changes in the fluid flow paths, such as three or less. In the illustrated embodiment, there are only two such changes of direction of the path across a surface of the center section 50.
As previously mentioned, the sections 40, 50 and 60 may be bolted together in one embodiment. To that end, the center section 50 may have threaded openings 55 on both its top and bottom faces, while the top 40 and bottom 60 have unthreaded openings 30 through which respective bolts (not shown) extend to engage the threaded openings 55 and thereby hold the top 40 and bottom 60 to the center section 50. It will be appreciated by one skilled in the art that although the steam generator 20 as disclosed herein has three sections 40, 50 and 60, the steam generator 20 can be fabricated using fewer or more sections as may be desirable in alternative embodiments.
The top 40 includes a pair of vanes 42 that engage the top-surface vanes 52 of the center section 50 (
The top 40 includes a plurality of spaced-apart members 44 disposed substantially adjacent to the outlet 24. These function as the filter structure 16 of
Liquids such as water from residential or commercial water supplies may contain dissolved minerals or other matter than can form deposits on the inner surfaces of the steam generator 20 from the heating of the liquid to vapor (e.g., water to steam). Typical minerals contained in water include calcium and magnesium, among other elements, compounds and minerals. The deposits or residues can precipitate out of the solution (e.g., water) as it is heated to vapor. Typically, the precipitates themselves are much smaller than the opening of the outlet 24, so they are discharged with the vapor and do not build up or otherwise cause clogging. However, larger particles can be created in the form of deposited material that has been freed from the inner surface during operation and that is carried by the liquid and vapor toward the outlet 24. Also, even the smaller precipitates themselves can cause buildup right at the outlet 24 over time, causing partial or complete blockage and degraded operation of the steam generator 20.
The array of members 44 provide the above-discussed filtering with increased surface area by virtue of extending across a relatively wide area adjacent to the outlet 24 and creating a large number of paths through which the vapor can travel toward the outlet 24. Any small number of spaces between members 44 may become clogged without substantially reducing the ability of the vapor to travel to the outlet 24. The vapor will naturally be directed around such clogs toward open spaces and paths through the members 44 to the outlet 24. It is only when most of these spaces become clogged that performance will degrade significantly, and this clogging occurs over a much longer period of time than the time required to clog the outlet 24 if no filtering were provided. Thus, the usable lifetime of the steam generator 20 can be significantly increased over other steam generators not employing such filtering.
As shown in
In some examples, the spacing S1, S2, S3 between the members 44 can be the same (e.g., S1=S2=S3=2 mm). In other examples, the spacing S1, S2, S3 between the members 44 can be different (e.g., S1=1 mm, S2=2 mm, S3=3 mm). Alternatively, the spacing S1, S3, S3 between the members 44 can be a combination thereof.
In one embodiment, the spacing S1, S2, S3 between the members 44 may be smaller than the diameter of the outlet 24. In operation, when the mineral deposits or precipitates are larger than the opening of the outlet 24, they may be trapped between the members 44. In the alternative, when the mineral deposits or precipitates are smaller than the orifice of the outlet 24, they are more likely to pass through the members 44 and be discharged through the outlet 24.
In some embodiments, the members 44 can take on a patterned grid formation or have an organized orientation or alignment. In other embodiments, the members 44 can be randomly distributed in the top 40 without any orientation or alignment. Alternatively, the members 44 can have a combination of configuration, orientation and alignment.
Although in the illustrated embodiment the members 44 are formed integrally with the top 40, in alternative embodiments similar members 44 or other components of a filter structure 16 may be part of a separate filter element that is inserted into the flow path.
In the above description of the steam generator 20, the inlet 22 is shown in the bottom 60, while the outlet 24 is shown in the top 40 and the heating element 52 in the center section 50. These items may be positioned differently in different embodiments. In many cases it will be desirable that the heating element be centermost to minimize undesirable heating of exterior surfaces of an appliance that contains the steam generator 20. In addition, although the steam generator 20 as shown includes three sections 40, 50, 60, it will be appreciated that alternative arrangements may employ more or fewer sections, or use of a single integrally formed unit.
In some embodiments, a steam generator as disclosed herein need not be pressurized. In other embodiments, the steam generator 20 disclosed herein may be pressured. In some instances, the steam generator 20 can be oriented in a vertical orientation in operation (i.e., inlet and outlet spaced apart in mostly a vertical direction), while in other instances, the steam generator 20 can be oriented in a horizontal orientation. Alternatively, the steam generator 20 can be oriented at multi-variable angles or in multi-variable directions/orientations when mounted within the steam appliance.
A steam generator as disclosed herein may have a relatively small footprint (e.g., smaller in size, weight) and be incorporated in a handheld steam apparatus such as a portable handheld steamer, among others, as described above. For example, the steam generator 20 can have a weight of not greater than about 500 grams, or not greater than about 400 grams, or not greater than about 300 grams, or not greater than about 200 grams, or not greater than about 100 grams.
A steam generator as disclosed herein can deliver a life expectancy of greater than 100 hours, or greater than 150 hours, or greater than 200 hours, or greater than 250 hours, or greater than 300 hours. In doing so, the steam generators 20 can pass greater than about 100 L of water, or greater than about 200 L of water, or greater than about 300 L of water, or greater than about 400 L of water, or greater than about 500 L of water through its inlet.
While in the above description the filter structure 16 is realized by the array of members 44, in alternative embodiments it may be realized in other ways. As an example, a sufficiently fine-grained metal mesh may be employed. A metal mesh or similar structure may advantageously provide a large surface area, extending the usable life of the steam appliance accordingly.
While various embodiments of the invention have been particularly shown and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims.
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