The present invention provides a flexible and stretchable wearable electronic device system. The system includes a sweat-activated battery that has an anode and a cathode and a dry electrolyte-impregnated carrier in contact with the anode and the cathode. A sweat-absorbing layer is in contact with the dry electrolyte-impregnated carrier. An adhesive layer is provided for attaching the sweat-activated battery to the skin of a user. A flexible electronic device such as a sweat sensor or a lighting element is connected to the sweat-activated battery and is powered by the sweat-activated battery.

The present invention provides a flexible and stretchable wearable electronic device system. The system includes a sweat-activated battery that has an anode and a cathode and a dry electrolyte-impregnated carrier in contact with the anode and the cathode. A sweat-absorbing layer is in contact with the dry electrolyte-impregnated carrier. An adhesive layer is provided for attaching the sweat-activated battery to the skin of a user. A flexible electronic device such as a sweat sensor or a lighting element is connected to the sweat-activated battery and is powered by the sweat-activated battery.

A reserve battery including: a housing has first and second compartments separated by a membrane, the first compartment has an anode and cathode and a separator positioned there between. The second compartment has an electrolyte for use with the anode and cathode to produce electrical power. The electrolyte being sealed in the second compartment relative to the first compartment at least by the membrane. Electrodes are connected to the anode and cathode and each has a portion on an outside of the housing. Where the second compartment has a cavity in which a wick material is arranged. The wick material is configured to pull the electrolyte into the second compartment from the first compartment by capillary action when the membrane changes from a sealed state in which the electrolyte is sealed within the second compartment to an unsealed state in which the electrolyte can flow into the first compartment.

A reserve battery including: a housing has first and second compartments separated by a membrane, the first compartment has an anode and cathode and a separator positioned there between. The second compartment has an electrolyte for use with the anode and cathode to produce electrical power. The electrolyte being sealed in the second compartment relative to the first compartment at least by the membrane. Electrodes are connected to the anode and cathode and each has a portion on an outside of the housing. Where the second compartment has a cavity in which a wick material is arranged. The wick material is configured to pull the electrolyte into the second compartment from the first compartment by capillary action when the membrane changes from a sealed state in which the electrolyte is sealed within the second compartment to an unsealed state in which the electrolyte can flow into the first compartment.

A moisture-sensitive device is provided that includes a fluid-sensitive battery. Exposure of the battery to urine or some other fluid causes the battery to provide a voltage that can be used to power a transmitter. The transmitter can then provide a wireless transmission indicative of the battery having been exposed to the fluid. This moisture-sensitive device can be provided in a diaper and transmissions produced by the device can be detected using a smart phone or other device and used to indicate to a user that the diaper has been soiled. By powering the transmitter using the fluid-sensitive battery and storing the battery in a dry state, such a device can be stored for a protracted period of time before use.

A moisture-sensitive device is provided that includes a fluid-sensitive battery. Exposure of the battery to urine or some other fluid causes the battery to provide a voltage that can be used to power a transmitter. The transmitter can then provide a wireless transmission indicative of the battery having been exposed to the fluid. This moisture-sensitive device can be provided in a diaper and transmissions produced by the device can be detected using a smart phone or other device and used to indicate to a user that the diaper has been soiled. By powering the transmitter using the fluid-sensitive battery and storing the battery in a dry state, such a device can be stored for a protracted period of time before use.

A packaging and shipping system for dry charged batteries. The packaging system includes a shipping crate having a lower section that defines an open interior. The open interior is sized to receive a dry charged battery and a plurality of electrolyte bottles. Each of the electrolyte bottles contains a volume of electrolyte sufficient to fill one of the individual cells of the dry charged battery. Each of the electrolyte bottles are separately packaged and positioned within the open interior of the shipping crate. Upon reaching the desired destination, the shipping crate can be stored. When the dry charged battery is to be placed into use, the shipping crate is opened and the individual cells of the dry charged battery are filled with electrolyte from the plurality of electrolyte bottles. Once the dry charged battery has been activated, the empty electrolyte bottles can be placed back into the shipping crate and returned for recycling.

A battery includes a casing that has an inner surface defining a chamber for an electrolyte, and a conductive lining being configured for electrical communication with a first battery terminal. There is also a permeable separator sheet disposed between the electrolyte and the conductive surface; a conductive rod having a first end configured for electrical communication with a second battery terminal, and, a second end configured for contacting the electrolyte. There is also an opening disposed in the casing; a sealing member configured for arrangement between at least a sealed position and an unsealed position to allow a potential difference to be produced between the first and second battery terminals. There is also at least one spacing element configured for spacing the electrolyte apart from the conductive lining within the chamber.

A battery includes a casing that has an inner surface defining a chamber for an electrolyte, and a conductive lining being configured for electrical communication with a first battery terminal. There is also a permeable separator sheet disposed between the electrolyte and the conductive surface; a conductive rod having a first end configured for electrical communication with a second battery terminal, and, a second end configured for contacting the electrolyte. There is also an opening disposed in the casing; a sealing member configured for arrangement between at least a sealed position and an unsealed position to allow a potential difference to be produced between the first and second battery terminals. There is also at least one spacing element configured for spacing the electrolyte apart from the conductive lining within the chamber.

The invention relates to an activation device for an electric battery unit, in particular, for a battery part of a torpedo. The invention also relates to a battery unit with activation devices of this type. An activation device incorporates an operating supply connection, to which an operating supply reservoir can be connected. A movably arranged cutting element can be pneumatically actuated via a pneumatic connection of the activation device by means of an actuation element, wherein a sealing element arranged in the path of travel of the cutting element controls the operating supply connection. In order to guarantee a safe storage, ready for operation, and a safe activation of a battery unit, it is provided in accordance with the invention that the activation device incorporates a pneumatic outlet, which can be fluidically connected to the pneumatic connection, depending on the position of the actuation element.