Patent Description:
The following background information may present examples of specific aspects of the prior art (e.g., without limitation, approaches, facts, or common wisdom) that, while expected to be helpful to further educate the reader as to additional aspects of the prior art, is not to be construed as limiting the present invention, or any embodiments thereof, to anything stated or implied therein or inferred thereupon. Exemplary wearables and wearable mounts comprising adhesives are known from documents <CIT> and <CIT>.

Wearables that are attached to the body by means of adhesives are positioned so to reduce the wearable impinging on the body during use. This is necessary to prevent discomfort for the user. User discomfort leads to reluctance in using the wearable as intended or even discontinued or sporadic use. The wearable must, therefore, accommodate the movement of the body and, due to this fact, wearables are implemented to be worn on portions of the body where surface changes are minimal, e.g., wrist, ear, leg and, where implementation must be elsewhere, the method of attaching the wearable to the body is difficult. The problem with these methods of attaching is that they also contribute in the creation of discomfort for the user via the use of belts, bands, articles of clothing, strong adhesives, large adhesives, and the like.

Conventional wearables often concentrate on large adhesives, covering the entire wearable and a significant amount of area around it with adhesive. Moreover, many conventional wearables use strong adhesives.

Wearables that are intended to collect and or monitor the wearer for a period of time are subject to exposure to moisture, which could lead to a risk that the wearer will short electrical contacts where present on the wearable. To address these issues, conventional wearables include covers to encase electrical ports when the wearable is being worn. Covering the electrical contacts, whether on the surface, protruding or recessed, to guard against contact with the skin is simple enough, however, covering these contacts to prevent or reduce moisture ingress results in the need for tighter sealing or other positive sealing methods. Invariably, these types of covers are rendered inoperative due to daily use either because they are torn off, deformed or damaged, resulting in the same risks identified above. Further still, attempts to make wearables even more robust results in larger form, demanding that the wearable increase in some dimension or dimensions to accommodate it. By nature of being a wearable, the intent is for the device to have a form as small and lightweight as possible to reduce strain on the skin, for functionality, aesthetics, and the like.

When a wearable has a port, the port is typically a micro Universal Serial Bus (USB) port recessed with flip covers, press covers, screw covers, and the like. Some conventional wearables further include a communication port which is present, but seldom used, for field upgrades.

Conventional wearables are at risk of being discarded or used sporadically resulting in reduced efficacy of its intended use. This is of particular interest when the intended use is within the treatment of a chronic disease or other application requiring consistent collection of data or monitoring. Therefore, ways in which users become engaged by the wearable apart from the designed use is an important part of wearable design and operation. Various strategies are employed, e.g., reducing the need for the user to remove the wearable; gamification of accompanying interaction apps and software that relies on consistent use; incorporating into jewelry and other items of clothing; incorporating into other accepted wearable systems like watches or earpieces and, maybe most important of all, allowing the user to change the appearance of the wearable as desired. Depending on the particular application, location of use, terms of use, and the like, the applicability of these approaches differs. Often, a wearable must be worn on the upper torso, be worn for the majority of a day, every day, be used by children and young adults, and the like. Additionally, the wearable should be manufactured at a relatively low cost and cost of use should be minimal. With these competing requirements, most of the above methods cannot be applied and the ability to change the appearance of the wearable is generally an upsell costing a lot more.

There are very few options for users to change the appearance of the wearable. Some conventional wearables that are limb worn, for example, have housings or bands that may be changed.

As can be seen, there are needs for wearables to make them attach to the body to accommodate movement while reducing the ability to cause discomfort for the wearer, to insulate and isolate the contacts whenever the device is in use without the use of sealing mechanisms, and to allow the appearance of the wearable to be changed to reflect the mood of the wearable.

A system for attaching a wearable to a user according to the present invention is defined in claim <NUM>.

In some embodiments, a sensor area of the wearable that needs contact with the skin or placement on a specific spot, provided that such a sensor is needed, has a flat circular area around it. Further still, ideally the wearable should be flexible to allow contouring with the body as it moves. A corresponding wearable mount (also referred to as adhesive layer) has a ring of adhesive corresponding to the designated flat portion of the wearable. This adhesive can be a high strength adhesive and bonds the adhesive layer to the wearable, i.e., does not contact the skin. The area in the center of the designated area of the adhesive layer can be a hole allowing sensors or other such device to contact the skin. The rest of the adhesive layer on the side of the wearable does not stick to the wearable. The skin side of the adhesive layer then has a spot of easy to remove adhesive at each point. For example, a triangular shape would have three spots, a four sided layer may have <NUM> spots, and the like. Additionally, the adhesive layer can be made from material with sufficient stretch to suit the movement of the body but contains memory allowing it to shrink. For example, if the adhesive layer is attached to the chest area, as someone bends forward using abdominal muscles, the points of the adhesive layer will get closer as the skin contracts, then bending outward may cause the chest area to expand, expanding the adhesive layer with it. Throughout this motion, the skin is not restricted by the reduced elasticity of the wearable, thus reducing the risk of the wearable being uncomfortable. Where the wearable is flexible, the changes in body contour is further accommodated. If a flexible wearable or fixed wearable is attached to the body, as the body moves, the skin stuck to the wearable is forced to shift or pull with the movement. This results in the wearable getting undone. Here, the current market solutions are to employ very strong adhesives or large adhesives covering a wearable. With this embodiment of the present disclosure, as the adhesive layer can stretch with the skin, easy to peel off adhesives can be used, which is important for long term use of wearables, thus reducing skin damage. With the present disclosure, as the skin moves around, the wearable "floats" on the wearable mount, reducing the discomfort.

In some embodiments, either incorporated on the wearable or attached as a layer, there is a layer of material that has a higher elasticity than the wearable and, to the extent of possible, skin movement. The wearable side of the adhesive layer can now connect with the wearable on many more points. This provides benefits such as accommodating many sensors, heavier wearables, wearable use under rigorous settings, and the like. So in this use case, as the skin moves, the highly elastic layer of the wearable moves to suit it thereby allowing the skin to move unrestricted thus reducing the discomfort. Again, both restricted and flexible wearables could be used.

The wearable has all of the necessary contacts on the skin side surface of the wearable, flush with it. Ordinarily, these contacts could touch the skin or moisture could run across them. By pairing and using the wearable only with a suitable adhesive layer, the adhesive layer covers the ports and insulates the ports from the skin. Additionally, adhesive rings can seal the ports, blocking moisture from penetrating to it and/or moving between contacts. The adhesive can be removed when the wearable is placed for charging, thus exposing the low power contacts. Before attaching for use again, a new adhesive is applied, as is required to reduce skin irritation, and, at the same time, to restore the insulating and isolating properties. The end result is that no additional infrastructure is required to affect these two important safeguards, thereby allowing the wearable to have a small form factor. Additionally, covers for ports of conventional wearables get damaged or lost, rendering the device inoperative. It should be noted that the device could be washed with the adhesive off, as wearables tend to have extensive power management components that could detect these activities and shut off the ports for this activity.

In some embodiments, the material used on the underside of the wearable be the same as the outer side, or at least compatible with the adhesive used on the underside. This feature allows an adhesive layer to be placed on the outside of the device. What this does is that it facilitates the sticking of any compatible material, such as paper, foil, plastic, or the like, that is configured as a different shape, color, pattern, or the like, on the outer side of the wearable, effectively changing the appearance of the wearable. This step is not possible today as most wearables have adhesives holding the actual wearable in place which cross the top or the top material is made from materials that are silicone based, reducing its ability to retain adhesives on it. Such a feature allows children to stick on paper, or the like, in different shapes, or with characters, or depicting objects, or the like, thereby giving them comfort as they use the device. It is akin to a child wearing an under vest with their favorite character printed on it as it gives them comfort, especially as they face an uncomfortable situation.

These and other features, aspects and advantages of the present disclosure will become better understood with reference to the following drawings, description and claims. BRIEF DESCRIPTION OF THE DRAWINGS.

Some embodiments of the present disclosure are illustrated as an example and are not limited by the figures of the accompanying drawings, in which like references may indicate similar elements.

Unless otherwise indicated illustrations in the figures are not necessarily drawn to scale.

The disclosure and its various embodiments can now be better understood by turning to the following detailed description wherein illustrated embodiments are described. It is to be expressly understood that the illustrated embodiments are set forth as examples and not by way of limitations on the invention as ultimately defined in the claims.

As used herein, the singular forms "a," "an," and "the" are intended to include the plural forms as well as the singular forms, unless the context clearly indicates otherwise.

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one having ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and the present disclosure and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

In the description, it will be understood that a number of techniques and steps are disclosed. Each of these has individual benefit and each can also be used in conjunction with one or more, or in some cases all, of the other disclosed techniques. Accordingly, for the sake of clarity, this description will refrain from repeating every possible combination of the individual steps in an unnecessary fashion.

Devices or system modules that are in at least general communication with each other need not be in continuous communication with each other, unless expressly specified otherwise. In addition, devices or system modules that are in at least general communication with each other may communicate directly or indirectly through one or more intermediaries.

A description of an embodiment with several components in communication with each other does not imply that all such components are required. On the contrary, a variety of optional components are described to illustrate the wide variety of possible embodiments.

As used herein, the term "wearable" or "wearable device" refers to any device that is configured to be worn by a user, typically a mammal user, such as a human. The wearable device may be useful in a variety of applications, such fitness trackers, for remote treatment or monitoring of disorders, as a sports tracker, for health monitoring and data collection, as a gauge for alertness or energy levels, as a navigation tool, as a communication tool, as a medication dispensing device, or the like.

Broadly, embodiments of the present disclosure relate to a wearable and/or a wearable mount that solves many issues presented with conventional wearables and wearable mounts. For example, the wearable mount can be designed with a low ratio of adhesive contact area to wearable mount contact area while providing the capability to collect data and/or dispense medication on one specific spot and, further still, allowing the use of an easy to remove adhesive. This configuration may facilitate free movement of the body even when the wearable mount is attached to the skin. The wearable may have surface contacts, removing the need for ports that could be damaged. The surface contacts can provide insulation and isolating properties for the contacts while the device is being worn. Finally, the wearable may be a patch-type wearable that allows the appearance of the wearable to be changed without the need for housing changes or other costly solutions.

Referring to <FIG>, a top view of a skin-contacting side <NUM> of an adhesive layer <NUM>, also referred to as a wearable mount <NUM>, is shown. The adhesive layer <NUM> can include a center adhesive <NUM> forming a closed ring and having a cutout <NUM> within the center adhesive <NUM>, indicating sensor location, for example. The cutout <NUM> may be dependent on the sensor requirements and may or may not be present. The adhesive <NUM> may be formed in various shapes. A triangular shaped adhesive <NUM> is shown in <FIG>.

Additional adhesive <NUM> may be disposed on the extremities of the adhesive layer <NUM>. For example, if the adhesive layer <NUM> is triangular, as shown, then the adhesive <NUM> may be disposed at each of the three corners of the triangular adhesive layer <NUM>. Similarly, if the adhesive layer <NUM> is rectangular or square, then the adhesive <NUM> may be disposed on each of the four corners of the adhesive layer <NUM>. While the Figures show the adhesive <NUM> at extremities of the adhesive layer <NUM>, other patterns of adhesive <NUM> to connect the adhesive layer <NUM> to the user's skin are contemplated. Regardless of design, typically, a low ratio of area of adhesive <NUM> to area of the bottom side <NUM> of the adhesive layer <NUM> is sufficient for attaching the adhesive layer <NUM> to the user's skin while permitting flexibility during movement of the user. This low ratio may, for example, result in the area of the adhesive <NUM> being less than <NUM>% of the total area of the bottom side <NUM> of the adhesive layer <NUM>. Often, the area of the adhesive <NUM> may be less than <NUM>% of the total area of the bottom side <NUM> of the adhesive layer, typically, even less than <NUM>% thereof.

Typically, wearables include adhesives that cover the entire skin side, giving rise to many of the issues discussed above. The adhesive placement of the present disclosure. can allow for a fixed region on the skin (when needed) via adhesive <NUM>, as well as allow flexibility by having adhesive <NUM> only at the extremities of the adhesive layer <NUM>.

The adhesive layer <NUM> may be formed from an elastic material. In some embodiments, the elastic material may have sufficient elasticity so that user movement is accommodated by the flexibility of the material, where the adhesive <NUM> remains attached to the skin during movement of the user. In this embodiment, the elastic material of the adhesive layer may be defined as a "high elasticity" adhesive layer.

Referring now to <FIG>, a wearable mounting side <NUM> of the adhesive layer <NUM> is shown. The wearable mounting side <NUM> can include a device side adhesive <NUM>. The device side adhesive <NUM> can be disposed generally in the vicinity of the sensors (not shown) of a wearable <NUM> (see <FIG>) to keep the wearable firmly bonded to the adhesive layer <NUM>. Moreover, the shape of the adhesive <NUM> can be designed to cover the contacts <NUM> of the wearable <NUM> (see <FIG>), as discussed in greater detail below.

Referring to <FIG>, a mounted wearable <NUM> can be attached to the adhesive mount <NUM>, where the adhesive <NUM> is used to attach the adhesive mount <NUM> to a user's skin. As can be seen, in some embodiments, the wearable <NUM> is attached to the adhesive mount <NUM> at a portion thereof thereby permitting flex of the adhesive mount <NUM> when the user moves. In this embodiment, the mounted wearable <NUM> may be stiff or flexible. In some embodiments, the mounted wearable <NUM> is flexible and can be attached to the adhesive mount <NUM> with a greater surface area of adhesive.

It should be noted that the adhesives <NUM>, <NUM>, <NUM> and the adhesive layer <NUM> can be designed in various thicknesses, colors, shapes and designs. Such embodiments, while not specifically illustrated or described, are included within the scope of the present disclosure.

<FIG>, a top side <NUM> of the wearable <NUM> is shown. <FIG> shows a bottom side <NUM>, also referred to as adhesive layer contacting side, of the wearable <NUM>. <FIG> shows the bottom side <NUM> of the wearable <NUM> being mounted to the adhesive layer <NUM>. As discussed above, typical wearables can include ports for charging, updates, data transfer, or the like. These ports can be damaged by moisture.

The wearable <NUM>, according to the present invention, can include flush contacts <NUM> positioned in a location where the wearable <NUM> is attached to the adhesive layer <NUM>. While a particular number and pattern of contacts <NUM> are shown in <FIG> and <FIG>, various numbers and patterns of contacts <NUM> may be used, as needed by a particular application. Therefore, when the adhesive <NUM> (see <FIG>) is attached to the wearable <NUM>, the adhesive <NUM> covers the contacts <NUM>. In some embodiments, as shown in <FIG>, adhesive <NUM> may be applied over the contacts <NUM> to ensure that the contacts are isolated and insulated. When access to the contacts <NUM> is needed, one can simply remove the adhesive <NUM>.

Referring now to <FIG> and <FIG>, the wearable <NUM> can include at least one adhesive adhering region <NUM> on a top surface thereof. The adhesive adhering region <NUM> can be formed from a material conducive to adhering to typical adhesives used for wearables. Typical top surfaces of wearables are made from materials to which wearable adhesives will not adhere, such as silicone. In embodiments of the present invention, disclosure, all or a portion of the top surface of the wearable <NUM> can be formed of a material similar to or the same as the bottom surface onto which adhesive <NUM> is capable of bonding.

With the presence of the adhesive adhering region <NUM>, a user can apply various cutouts <NUM>, such as that shown in <FIG>, by the use of the same adhesive used to apply the wearable <NUM> to the adhesive mount <NUM>. Thus, the user can change the color and design of the outer surface of the wearable <NUM> as desired. If a further change is desired, the user can simply remove the cutout <NUM> and its adhesive and attach a new design via additional adhesive. The cutout <NUM> shown in <FIG> is an Iron Man power source image and is the property of Marvel Comics. This cutout <NUM> is shown only as an example, and various sizes, shapes, designs, colors, and the like, of the cutout <NUM> are contemplated.

The above embodiments provide several features to distinguish itself from conventional wearable and wearable mounts. Some of these features, while not inclusive of all such features, are described below.

Embodiments of the present disclosure allow the use of less adhesives, thereby reducing the risk of skin irritations. In these embodiments, spots of adhesive are placed on the corners and at the main sensor area rather than on the entire profile of the adhesive layer. Embodiments of the present invention further allow the use of easy peel adhesives that reduce the risk of damaging the skin. Conventional wearables often use bandage-type adhesives intended for wound closures. Embodiments of the present disclosure allow the wearable to move independently of the skin except for the small central anchor point, thereby reducing discomfort arising from movement. Conventional wearables use fixed adhesives solidly bonded to the skin thereby restricting the skin from moving freely. The arrangement of adhesives reduces the amount of adhesives used in each application, reducing the overall cost of the adhesive component, thereby reducing the operating cost of the system.

Embodiments of the present disclosure allow power and communications to take up as little space as possible, basically just the space of surface contacts. Conventional wearables include bulky ports dictating the thickness of the wearable. The present invention allows electrical contacts to be insulated and isolated with the same adhesive being used each day. Conventional wearables have port covers and slides that get torn or lost rendering the device inoperable. The contacts of the present invention are generally a lot less expensive than ports with covers. Moreover, the contacts of the present invention reduce the complexity of the manufacturing process.

Embodiments of the present disclosure allow the wearable to have its appearance changed by simply sticking new patterns on it via the use of already supplied adhesive. This allows the appearance media to be of simple manufacture, such as a printout or cutout, or the like. This further allows the wearable to take on shapes and characters that are appealing to the user, thereby increasing adherence to using.

Claim 1:
A system for attaching a wearable (<NUM>) to a user, comprising:
a wearable mount (<NUM>) having a skin contacting side (<NUM>) and a wearable contacting side (<NUM>);
a first adhesive (<NUM>) on a portion of the skin contacting side for adhering the wearable mount to the skin, the portion being <NUM> percent or less of the area of the skin contacting side of the wearable mount;
a second adhesive (<NUM>) on a portion of the wearable contacting side of the wearable mount, the second adhesive attaching a portion of the wearable to the wearable mount; and
a continuous perimeter of additional adhesive (<NUM>) disposed about a central area of the interior of the skin contacting side of the wearable mount, the continuous perimeter having a space formed therewithin, wherein the space is a cutout (<NUM>) formed in the wearable mount; and
a wearable (<NUM>) attached to the second adhesive, the wearable including:
a top surface;
a bottom, opposite surface configured to adhere to a wearable mount; and
one or more contacts (<NUM>) disposed as flush mount contacts on the bottom surface of the wearable and in a region where the second adhesive (<NUM>) adheres the wearable (<NUM>) to the wearable mount (<NUM>),
wherein the second adhesive is configured to cover the one or more contacts (<NUM>) disposed on the wearable, electrically isolating and insulating the contacts;
wherein the wearable mount is formed in a shape having comers; and
wherein the first adhesive is disposed as a single spot of adhesive placed on each of the corners of the skin contacting side of the wearable mount.