Disclosed is a water container for camping. The water container for camping of the present invention comprises: a connector part which is coupled to a main body in which water is stored and provided as a discharge passage of the water stored in the main body; an opening/closing part which is coupled to the connector part and provided as an air passage while discharging the water flowing into the connector part by opening/closing one side portion of the connector; and a water inflow prevention part of which one side portion is floated by the water stored in the main body and the other side portion is connected to the connector part so as to prevent the water from flowing into a passage of air to be discharged through the connector part and the opening/closing part.

A method of forming a canister by means of a mechanical bonding of respective layers of a first metal material (tantalum) and a second metal material (niobium) to form a sheet stock, thereby forming the sheet stock into a canister form, wherein the first metal material comprises tantalum and the second metal material comprises at least one of niobium, molybdenum, or steel. The completed canister comprises a first metal material comprising tantalum, and a second metal material mechanically bonded to the first metal material by subjecting the first and second metal materials to at least 1,000,000 psi, to thereby form a canister having an inner diameter of 13-19 millimeters (mm), the second metal material comprising at least one of niobium, molybdenum, or steel.

A method of forming a canister by means of a mechanical bonding of respective layers of a first metal material (tantalum) and a second metal material (niobium) to form a sheet stock, thereby forming the sheet stock into a canister form, wherein the first metal material comprises tantalum and the second metal material comprises at least one of niobium, molybdenum, or steel. The completed canister comprises a first metal material comprising tantalum, and a second metal material mechanically bonded to the first metal material by subjecting the first and second metal materials to at least 1,000,000 psi, to thereby form a canister having an inner diameter of 13-19 millimeters (mm), the second metal material comprising at least one of niobium, molybdenum, or steel.

A method of forming a canister by means of a mechanical bonding of respective layers of a first metal material (tantalum) and a second metal material (niobium) to form a sheet stock, thereby forming the sheet stock into a canister form, wherein the first metal material comprises tantalum and the second metal material comprises at least one of niobium, molybdenum, or steel. The completed canister comprises a first metal material comprising tantalum, and a second metal material mechanically bonded to the first metal material by subjecting the first and second metal materials to at least 1,000,000 psi, to thereby form a canister having an inner diameter of 13-19 millimeters (mm), the second metal material comprising at least one of niobium, molybdenum, or steel.

A method of forming a canister by means of a mechanical bonding of respective layers of a first metal material (tantalum) and a second metal material (niobium) to form a sheet stock, thereby forming the sheet stock into a canister form, wherein the first metal material comprises tantalum and the second metal material comprises at least one of niobium, molybdenum, or steel. The completed canister comprises a first metal material comprising tantalum, and a second metal material mechanically bonded to the first metal material by subjecting the first and second metal materials to at least 1,000,000 psi, to thereby form a canister having an inner diameter of 13-19 millimeters (mm), the second metal material comprising at least one of niobium, molybdenum, or steel.

The invention is for a heating pad for a container to lie against at least one external surface of the container, and apply thermal energy to the container, and any material therein, when needed. The pad consists of a foamed resilient substrate with a first presenting major surface substantially equal in area to the at least one external surface of the container. A heating cable is located on the first presenting major surface to form an electrical circuit that when energised provides the thermal energy. A planar sheet material is above the first presenting major surface, and below a second presenting major surface of the substrate, the planar sheet material extends past the first and second presenting major surfaces and sealed at a periphery to form an encapsulation of the substrate and heating cable. There is an electrical connection from the heating cable internally of the encapsulation to external of the encapsulation. Such that the heating pad can be located against the at least one external surface of the container to move with that container, and when connected to a source of electricity can supply thermal energy to the container and any material contained therein.

The invention is for a heating pad for a container to lie against at least one external surface of the container, and apply thermal energy to the container, and any material therein, when needed. The pad consists of a foamed resilient substrate with a first presenting major surface substantially equal in area to the at least one external surface of the container. A heating cable is located on the first presenting major surface to form an electrical circuit that when energised provides the thermal energy. A planar sheet material is above the first presenting major surface, and below a second presenting major surface of the substrate, the planar sheet material extends past the first and second presenting major surfaces and sealed at a periphery to form an encapsulation of the substrate and heating cable. There is an electrical connection from the heating cable internally of the encapsulation to external of the encapsulation. Such that the heating pad can be located against the at least one external surface of the container to move with that container, and when connected to a source of electricity can supply thermal energy to the container and any material contained therein.

Fusing nanowire inks are described that can also comprise a hydrophilic polymer binder, such as a cellulose based binder. The fusing nanowire inks can be deposited onto a substrate surface and dried to drive the fusing process. Transparent conductive films can be formed with desirable properties.

A beach toy bucket includes a housing and a rim. The housing has a bottom and one or more walls defining a cavity. The one or more walls include a first end and a second end. The bottom is disposed at the first end of the one or more walls. The rim is disposed at the second end of the one or more walls and collectively defines a shape surrounding the cavity. The housing and the rim are formed from a compostable material.

An adaptable, cleanable beverage container, generally for athletic use, with an enlarged opening at the top for depositing materials and flavors, a removable base for ease of cleaning, and an optionally insertable column removably connected to said removable base for securing a cooling or heating fluid or gel into the container. Optionally, the beverage container walls can be insulated with a hearing or cooling gel or other liquid for providing temperature control.