Patent Application
20200072548
The present description relates to drying of electronic devices, and, more specifically, to a passive drying apparatus, system, and method, which can be used to remove water from wet electronic devices, such as cellular telephones.
Electronic devices, unless they are waterproof, often will not work after they get wet. For example, a common cause of damage to cellular telephones is water that has entered into the phone, such as from falling into a bathtub or swimming pool. Some electronic devices can be restored to working condition by removing the water that has entered into the devices.
There are passive and active methods of drying wet electronic devices, such as cell phones. As used herein, passive means any method that does not require the use of any electrically powered devices, such as pumps, compressors, and heaters. Also, as used herein, active methods rely on the use of electrically powered devices, such as pumps, compressors, and heaters. One example of a passive method of drying electronic devices is to place the wet device in a desiccant or a material (such as dry rice) that will absorb water by diffusion and absorption
An example of an active method is part of a service offered by TekDry, LLC of Denver, Colo. The TekDry™ method employs an electrically powered system that includes a drying chamber into which a wet electronic device is placed. The chamber is coupled to an electrically powered vacuum pump that maintains the pressure inside the chamber at a partial vacuum when the pump is turned on. Also, the chamber is heated by an electrically powered heater that heats the drying chamber while the vacuum pressure is maintained. However, the TekDry™ system is expensive and is only available as a service offered at certain retail locations. The financial cost of the system may be many times greater than the replacement cost of a respective wet electronic device, making a consumer purchase of such active drying system impractical. Further, the size of the TekDry™ system is large and impractical to store, especially when the system will likely be used infrequently. Thus, such active systems are not cost effective or practical for consumer users to own, and may be impractical for those consumers who are geographically too far to avail themselves of the TekDry™ service at the limited number of available retail locations.
A kit is described that can be used for passively drying an electronic device that has become wet. According to one embodiment, a kit for drying an electronic device includes a sealed, negative pressure, vacuum container having a chamber that has been depressurized to a partial vacuum, and a drying container operably couplable to the containerized vacuum. The drying container includes a desiccant chamber containing a desiccant and an electronic device-receiving main chamber in fluid communication with the desiccant chamber. The main chamber is sized for housing a personal electronic device, such as a cell phone. The drying container may include a port at which to fluidly couple to the vacuum container.
The kit may further include a chemical heater couplable to the drying container and configured to heat the main chamber to a temperature above 80 degrees Fahrenheit (e.g., between 80 and 130 degrees Fahrenheit), and the drying container may include a heater housing adjacent to the main chamber configured to house the chemical heater, and the heater housing is thermally coupled to the main chamber.
The drying container may have an open first end defining a slot in communication with the main chamber. The slot is configured to receive the electronic device therethrough, and to be sealed closed. The port of the drying container may include a breakable seal or a one-way valve configured to open when fluidly coupled to the vacuum container. The desiccant chamber may be disposed between the main chamber and the port. In embodiments, the kit may include a seal attached to the first end of the drying container, and the open first end of the drying container may be configured to be sealed closed. Also, the drying container may have indicia indicating a location for cutting the drying container, such as to access the interior of the container to remove the electronic device therefrom after the first end is sealed closed.
The desiccant chamber may be bounded by porous fenestrated walls configured to contain the desiccant therebetween. The desiccant may be configured to change color as it absorbs water. The desiccant chamber may be configured to permit visual observation of the desiccant from outside of the drying container.
In embodiments, the vacuum container includes a first port sealed with an openable or breakable seal, and the drying container includes a second port in fluid communication with both the main chamber and the desiccant chamber. The second port is configured to couple to the first port, and the seal is configured to be opened or broken in during fluidly coupling of the second port to the first port. For example, the second port may include an opening element configured to pierce the seal of the first port as the first port is coupled to the second port.
According to another aspect, a method of drying an electronic device is described that includes providing a kit for drying the electronic device. The kit includes a sealed vacuum container having a chamber that has been depressurized to a partial vacuum. The drying container includes a desiccant chamber and a main chamber in fluid communication with the desiccant chamber. The main chamber is configured for housing an electronic device. The method further includes placing the electronic device inside the main chamber, sealing the drying container with the electronic device inside the main chamber, and fluidly coupling the vacuum container to the drying container to place the main chamber, desiccant chamber, and the vacuum chamber in fluid communication with each other. The vacuum chamber may be stored with a vacuum pressure of 1 Torr to 20 Torr. In use, a personal electronic device is placed inside the main chamber of the drying container and the main chamber is sealed. Then, the first port and the second port are coupled together and the breakable seal of the vacuum container is broken, which causes the chamber of the vacuum container to come into fluid communication with both the main chamber and the desiccant chamber of the drying container. As a result of the fluid communication, the main chamber and the desiccant chamber are depressurized until an equilibrium is reached between the chamber of the vacuum container and the main chamber and desiccant chambers of the drying container, at which all will be at a partial vacuum.
The kit may also include a chemical heater coupled to the drying container and configured to heat the main chamber when the heater is chemically activated, and the method may further include activating the chemical heater to heat the main chamber of the drying container. The method may also include heating the main chamber to a temperature above 80 degrees Fahrenheit (e.g., between 80 and 130 degrees Fahrenheit). The method may include observing a color change of the desiccant over time as the desiccant absorbs water extracted from the electronic device.
According to another aspect of the invention, a kit is described for drying an electronic device that includes a pressurized container holding a certain quantity of compressed dry gas at a pressure above atmospheric pressure. The pressurized container has a sealed outlet port. The kit also includes a drying container operably coupled to the pressurized container. The drying container includes a desiccant chamber and a main chamber in fluid communication with the desiccant chamber. The main chamber is configured for housing an electronic device. The drying container also includes a sealed inlet port, and a valve train and eductor fluidly coupled to the container between the main chamber and the sealed inlet port. The valve train may include a first valve fluidly coupled between the main chamber and the eductor, and a second valve fluidly coupled between the eductor and the inlet port of the drying container. The inlet port is configured to fluidly couple to the outlet port of the pressurized container.
The vacuum container 104 is a sealed container that has a vacuum chamber that has been depressurized to hold a negative pressure (at a partial vacuum below atmospheric pressure). The vacuum pressure inside the storage container may be around 1 Torr to 20 Torr, for example. The vacuum container 104 is configured to be fluidly coupled to the drying container 102 via a connection between a port 108 of the vacuum container 104 and a port 102c of the drying container 102, further details of which are described herein below. The port 108 may be sealed by a breakable seal 101. Also, or alternatively, the port 108 may have a one-way valve (not shown) that is normally closed when the port 108 is disconnected from the port 102c, but may be opened by fluidly coupling the port 108 to the port 102c of the drying container 102, as described in greater detail hereinbelow.
The drying container 102 may be conceptualized as having a plurality of portions, including a main chamber 102a, a desiccant chamber 102b, a port 102c, a breakable portion 102d, and a closure portion 102e. The main chamber 102a is defined by a wall 111 that may be formed of stiff plastic, such as polycarbonate, to house an electronic device (e.g., a cellular telephone). In one embodiment, the wall 111 of the main chamber 102a is configured to withstand a vacuum of about 1 Torr to 20 Torr without causing the wall 111 to buckle or collapse. This is intended to prevent a situation where the electronic device may become fully encapsulated by collapsed wall 111 and sealed off from the desiccant chamber 102b, which will inhibit drying the electronic device. In one embodiment, the wall 111 has at least one portion that is clear to permit visual observation of the interior of the main chamber 102a from outside the drying container 102. The main chamber 102a has internal dimensions to accommodate the electronic device. For example, the internal dimensions may be about 8 inches long, 5 inches wide, and 0.75 inch high to accommodate a cell phone.
The desiccant chamber 102b, which contains desiccant 105, is adjacent to the main chamber 102a. The desiccant chamber 102b is in fluid communication with the main chamber 102a and the port 102c. The desiccant chamber 102b may have fenestrated porous barriers 107 (
The port 102c is coupled to the desiccant chamber 102b opposite the main chamber 102a, and extends to an end 117 of the drying container 102. The port 102c is configured to mechanically and fluidly couple with the port 108 of the vacuum container 104. As shown in the embodiment of
The breakable portion 102d is on a side of the main chamber 102a opposite from the desiccant chamber 102b. The breakable portion 102d may include an annular portion of flexible material 110 that extends from the main chamber 102a to the closure portion 102e. The flexible material 110 is less rigid than the wall 111 of the main chamber 102a, but will bend when subject to a pressure range of 1 Torr to 20 Torr vacuum. In one embodiment, the material 110 of the breakable portion 102d is formed of an airtight, non-adhesive, leathery plastic material and may have a thickness of about 1 mm.
As shown in
The closure portion 102e defines a slot 119 (
The sealing flaps 114 may include a single-use closure means, such as an adhesive. For example, a pressure-sensitive adhesive tape may be attached to one sealing flap 114 while an opposed sealing flap 114 does not have such tape. The tape may include a layer of adhesive having one side of which directly attached to the corresponding flap 114 and having an opposite side directly attached to a releasable layer, which may be paper or plastic film, which can be peeled away to expose the unattached side of the adhesive layer. Thus, when used, a user can expose the adhesive layer of the tape on one flap 114 by peeling back the outer film layer and pressing the other flap 114 against the exposed adhesive to form an airtight seal between the two flaps 114.
Alternatively, the sealing flaps 114 may include a reclosable seal that can be unsealed and resealed at least once, which may eliminate the need for cutting the breakable portion 102d to open the drying container 102, as discussed above. For example, a resealable closure may use an interlocking seal, such as a ZipLoc™ seal used on ZipLoc™ storage bags.
The sealing flaps 114 are preferably less rigid than the material of the wall 111 of the main chamber 102a so that when subject to a pressure range of 1 Torr to 20 Torr vacuum the flaps will bend, but not break or collapse.
A workflow for using the kit 100 in a drying operation to dry an electronic device will now be described with reference to
As the drying operation progresses, water will be displaced from the electronic device 150, which can be absorbed by the desiccant 105, which can change color over time as water is absorbed. A user can view the color change of the desiccant 105 over time to gauge the rate of progress of water removal and whether the drying operation has ended. For example, a user can observe the color of the desiccant at periodic times and when the user notes that the color stops changing, the user can determine that water absorption has ended. The lack of further color change may indicate that the drying process is complete and that no further water needs to be removed from the electronic device. Sufficient desiccant 105 is provided to dry out the electronic device of water in a single use.
When the drying process is complete, a user can remove the electronic device 150 from the drying container 102, either by cutting the breakable portion 102d as discussed above, or by unsealing the flaps 114 if they are readily unsealable (i.e., if they are not adhesively sealed).
As noted above, the heater 120 is configured to raise the temperature of the main chamber 102a′ to a temperature above 80 degrees Fahrenheit. At room temperature, water will boil at a vacuum pressure of around 10 Torr. Thus, if the main chamber 102a experiences an elevated temperature above 80 degrees Fahrenheit and a vacuum pressure of between 1 Torr to 20 Torr, water in the electronic device 150 will evaporate quickly and speed up the water removal from the device, compared to the drying workflow of using the kit 100 without the heater 120.
Unlike vacuum container 104, the positive pressure storage container 204 contains a compressed, dry gas (i.e. nitrogen or air) at a high pressure above atmospheric pressure. The pressurized storage container 204 has a port 208 constructed in the same manner as port 108 and may be sealed by a breakable seal 201 or may have a one-way valve. Such seal 201 or one-way valve may be punctured or opened by the opener 203 as the port 208 is coupled to the port 202c. Also, the port 208 has male threads 209.
The kit 200 may be used to dry an electronic device 150 in accordance with a workflow, described herein with reference to
It will be appreciated that the container 202 may be modified to include a secondary chamber and heat source, such as chamber 102f and heat source 120, directly below the main chamber 202a.
The kits and methods described herein provide various benefits over electronic device drying services like TekDry™. For example, the methods and kits described herein can be used rapidly, and without delay caused by a user having to locate and travel to a specific location offering a drying service, such as TekDry™. Such delay and transportation of the device can risk causing more damage to the device. Thus, rapid desiccation may save electronic devices that would otherwise be ruined by moisture in circuitry. The kits described herein may be purchased and stored in advance by a user for ready access and use when needed, so that an electronic device may be dried out quickly and passively after being wet. Furthermore, the kits and methods described herein may be useful in situations, such as camping, where electricity is not readily available.
There have been described and illustrated herein several embodiments of a kit and a method of using the kits for drying an electronic device. While particular embodiments of the invention have been described, it is not intended that the invention be limited thereto, as it is intended that the invention be as broad in scope as the art will allow and that the specification be read likewise. Thus, while particular seal and connection arrangements have been disclosed, it will be appreciated that other seals and connection arrangements may be used as well. Also, while vacuum storage containers and positive pressure containers have been disclosed, each can be generally referred to as a storage container having a chamber retained at a non-ambient pressure. It will therefore be appreciated by those skilled in the art that yet other modifications could be made to the provided invention without deviating from its spirit and scope as claimed.
