Aspects of the present invention relate to entanglement prevention in brush assemblies in autonomous robotic vacuums.
Autonomous robotic vacuums often work in rooms on a schedule, when the user is not present. As such a vacuum traverses an environment, the vacuum picks up dirt, dust, lint, hair, and other debris and collects it in an onboard bin. In environments where substantial amounts of hair fall on the ground, brushes on board an autonomous robotic vacuum pick up the hair. Such pick up is known to cause clogging of the brush assembly, and in particular the hub on which the brush(es) is/are mounted, potentially preventing the brush(es) from rotating, and thus keeping the vacuum from operating properly. As such vacuums tend to be battery operated, the battery can run down before the vacuum finishes traversing the environment. Alternatively, if the vacuum keeps moving with the clogged brush assembly, proper cleaning cannot occur.
When the user returns, s/he may not know that there has been an entanglement. In that situation, the user may simply recharge the vacuum and set it again to operate when the user is away. However, the vacuum will not clean, because the entanglement still is there. As a result, the user will come home and find that the vacuum has not performed its intended tasks.
If the user examines the vacuum, s/he may see the entanglement. The user then has to remove the entanglement manually. However, in some circumstances the user may not see the entanglement, around the hub, very clearly. Also, even if the user does see the entanglement, it may not be easy to remove. Over time, the buildup of hair and debris could cause fatal damage to the robotic vacuum.
It would be desirable to provide an approach which avoids entanglement in the first instance.
In view of the foregoing, it is an object of the present invention to provide an apparatus which draws or leads hair and other potential entanglement debris away from the hub of a brush assembly as the brush rotates during vacuuming, thus avoiding or reducing entanglement and attendant problems, and obviating or reducing the need for manual removal of the entanglement.
In one aspect, an effect of the entanglement prevention apparatus is to enable the brush to be closer to the hub, enabling the brush to clean more effectively.
As now will be described in detail with respect to one or more embodiments, in one aspect the invention provides an apparatus which attaches to a vacuum brush, enabling the brush to rotate freely. The apparatus has a profile which draws hair and other entanglement debris away from a hub of the brush assembly, or prevents it from reaching the hub, thus enabling the brush/brush assembly to continue to rotate freely.
In one aspect of the invention, any number of autonomous robotic vacuums which operate with a brush assembly may employ the entanglement prevention apparatus described herein. One example of a robotic device which has vacuuming as one of its functions is described in U.S. Pat. No. 7,555,363, commonly assigned with the present application. The contents of this patent are incorporated herein by reference.
Looking at
Each of the components of apparatus 100 now will be discussed in more detail. In an embodiment, first endpiece 110 may be generally circular in cross section, except for a tongue-shaped extension 112 which in some circumstances can facilitate holding the structure fast to a brush housing assembly. In an embodiment, the endpiece 110 may be made of plastic. Other materials which facilitate snap fitting or other attachment to second endpiece 160 also are possible.
Endpiece 110 has a first side 114 and a second, opposite side 116. Sides 114 and 116 are sized to accommodate insert 120, as now will be discussed.
In an embodiment, insert 120 has a generally circular portion 122 and an extension 124 which is shaped to engage with the above-mentioned brush assembly. In an embodiment, extension 124 may have raised portions 126 which facilitate firmer engagement with the brush assembly. Circular portion 122 has a first surface, facing extension 124, with a first radius, and a second surface, on an opposite of the first surface, having a second, larger radius. In an embodiment, the progression from the first radius to the second radius is smooth and generally continuous. As a result, the circular portion 122 has a profile which variously may be known to ordinarily skilled artisans as a bevel, a chamfer, a taper, a slanted or angled surface, or a truncated cone. Each of these terms can have meanings which are synonymous or which are slightly different from each other. In the description herein, for convenience, the shape will be referred to as a bevel. However, this term should be understood to be shorthand for any of the several terms just mentioned, with corresponding definitions being applicable. Thus, for example, in the context of the present disclosure, something that is referred to as a chamfer will be understood also to be a bevel, a taper, a slanged or angled surface, or a truncated cone. Calling a structure one of these names does not prevent it from being known under one of the other names.
The bevel profile of circular portion 122 fits in a complementary fashion with a corresponding concave profile of side 116 of endpiece 110. The fitting is such that, when endpieces 110 and 160 are mated (snap fit) to each other, insert 120 rotates freely within the assembly comprising endpieces 110 and 160. Also, the profile of side 114 complements the shape of circular portion 122. Side 114′s profile, the smaller part of the bevel profile, faces the brush assembly, as will be seen. Elements 130, 140, and 150, which will be discussed in more detail below, facilitate the free rotation of insert 120.
Bar 130, which in an embodiment is metal, fits in an opening in insert 120. Bar 130 may be force fit into insert 120, or otherwise may be firmly attached or adhered to insert 120. In an embodiment, washer 140 may have an opening corresponding to that of a diameter of bar 130, and may facilitate rotation of bar 130 within insert 120.
Bushing 150, which in an embodiment also is metal, has a flanged portion 152 and a cylindrical portion 154. Cylindrical portion 154 may fit into an opening in second endpiece 160. This fit may be a force fit or a press fit, or other kind of attachment or adherence that puts bushing securely in the second endpiece 160. An end of bar 130 may slide into an opening in bushing 150. The metal to metal contact between bar 130 and bushing 150 reduces friction, and enables the bar 130 to rotate freely within the bushing 150. Alternatively, for example, bushing 150 may be made of nylon, plastic, or other material which produces relatively little friction when in contact with bar 130. As another alternative, bearings may replace bushing 150. As yet another alternative, bar 130 may be made of a material other than metal. However, where torqueing of extension 124 in insert 120 potentially is an issue, having the bar 130 be made of more rigid material can be desirable.
Second endpiece 160 may be made of a material which facilitates a press fit or a snap fit with first endpiece 110. On a side opposite the side of endpiece 160 into which bushing 150 fits, there may be extensions, 162, 164 which facilitate attachment of apparatus 100 into a larger structure, such as an underside of a vacuum, which in an embodiment is an autonomous robotic vacuum.
In
It has been discovered that the bevel shape of first endpiece 110, into which insert 120 fits, tends to effectively guide hair and other potential entanglement debris away from the hub in which brush assembly 300 is mounted, or prevent such debris from reaching the hub in the first place. As a result, debris will not wrap around any portion of the bushing or bearing mechanism, potentially fouling it. Hair or fibers have difficulty going from a smaller diameter to a larger diameter along the bevel as the assembly rotates. The bevel creates a barrier to keep fiber or hair from impinging on the bushing or bearing, preventing clogging. The effect of this structure is to enable the brush 310 to be positioned more closely to the hub on which brush assembly 300 is mounted, enabling a longer brush which can clean more surface during a pass of the robotic device. As a result, the brush 310 can clean more effectively within the overall robotic vacuum structure (actually, closer to the outer edges of that structure), in part because of the brush proximity to the hub.
What has been described here is a brush assembly for use in an autonomous robotic device with various capabilities. The robotic device's autonomy is in contrast to a remote control operation of the device. Autonomy enables the robotic device to operate without supervision or external influence, for example, to clean the environment, or zones within the environment in which the robot is operating. The entanglement prevention feature described herein works well with an autonomous robotic device which may operate, for example, on a schedule when the owner/user/operator is unavailable (for example, in the case of a home robotic vacuum, away from home). Entanglement prevention means that, for example, while the owner/user/operator is unavailable, the autonomous robotic device may operate with lessened risk of non-functionality, or battery drain, or the like because of fouling or other impeding of rotation of the brush assembly.
The brush assembly, of which the entanglement prevention apparatus described herein is a part, may be part of a home robotic vacuum, but also may be configured as a cartridge which a user may select from among several types of cleaning cartridges or modules (e.g. waxers, dusters, buffers, mops, or other types of cleaners). That is, an autonomous robotic device employing a brush assembly with the entanglement prevention apparatus described herein may be configured to receive different kinds of cleaning cartridges or modules, so as to perform as a floor cleaning product which performs different types of cleaning, not just vacuuming. A non-limiting example of such a cartridge configuration again may be seen in U.S. Pat. No. 7,555,363.
Although the invention has been described in language specific to structural features and/or methodological steps, it is to be understood that the invention is not to be limited to the specific features or steps disclosed. Rather, the specific features and steps are disclosed as preferred forms of implementing the invention, which is to be defined by the claims.
The present application claims the benefit of U.S. Provisional Patent Application No. 62/167,818, filed May 28, 2015, incorporated by reference in its entirety herein.
Number | Date | Country | |
---|---|---|---|
62167818 | May 2015 | US |