A bottle having a water volume measuring function comprises a bottle-lid, a bottle-body, and a measure module disposed in the bottle-lid which comprises at least a micro controller unit, a memory unit and a sound wave transceiver unit. The memory unit stores a lookup table with corresponding relationships between a plurality of frequencies and remained water volumes in the bottle-body. The sound wave transceiver unit emits sound waves with sweeping frequencies towards the bottle-body and receives reflected waves. The micro controller unit determines if any frequency of the sound waves is an air-resonance frequency according to the energy level of each of the reflected waves. When a sound wave frequency is determined as an air-resonance frequency, the micro controller unit obtains the corresponding remained water volume by checking with the air-resonance frequency in the lookup table and users can view the remained water volume without opening the bottle-lid.

A bottle having a water volume measuring function comprises a bottle-lid, a bottle-body, and a measure module disposed in the bottle-lid which comprises at least a micro controller unit, a memory unit and a sound wave transceiver unit. The memory unit stores a lookup table with corresponding relationships between a plurality of frequencies and remained water volumes in the bottle-body. The sound wave transceiver unit emits sound waves with sweeping frequencies towards the bottle-body and receives reflected waves. The micro controller unit determines if any frequency of the sound waves is an air-resonance frequency according to the energy level of each of the reflected waves. When a sound wave frequency is determined as an air-resonance frequency, the micro controller unit obtains the corresponding remained water volume by checking with the air-resonance frequency in the lookup table and users can view the remained water volume without opening the bottle-lid.

The present invention relates to a tube closure assembly. The assembly includes a tube head that includes a neck and a closure liner sealing said neck, and a cap that includes a punch provided with at least one tooth. The one or more teeth are configured to peripherally cut said closure liner. The cap is configured to transition from an open flush position, in which the one or more teeth are flush with said closure liner, to a perforation position, in which the one or more teeth perforate the closure liner, then from the perforation position to an end-of-travel position allowing partial cutting of the closure liner, the transition from the perforation position to the end-of-travel position being carried out with an angular rotational range below 360°.

The present invention relates to a tube closure assembly. The assembly includes a tube head that includes a neck and a closure liner sealing said neck, and a cap that includes a punch provided with at least one tooth. The one or more teeth are configured to peripherally cut said closure liner. The cap is configured to transition from an open flush position, in which the one or more teeth are flush with said closure liner, to a perforation position, in which the one or more teeth perforate the closure liner, then from the perforation position to an end-of-travel position allowing partial cutting of the closure liner, the transition from the perforation position to the end-of-travel position being carried out with an angular rotational range below 360°.

Disclosed is container for modifying temperature of an object on receiving commands from a computing device. The container includes a hollow outer vessel, a hollow inner vessel, a hollow cylindrical bracket, a first temperature sensor, a peltier element, a heat sink, a second temperature sensor, a battery, a printed circuit board, a memory unit, a microprocessor, a bi-directional communication unit, and a bottom cover. The hollow cylindrical bracket is having a first indent, a second indent, a sidewall, and a closed bottom end. The hollow bracket sidewalls move between the second outer surface and the first inner surface. The first temperature sensor measures temperature of the second outer surface of the inner vessel. The memory unit stores pre-defined reference temperature. The microprocessor processes signals received from the first temperature sensor and the second temperature sensor. The microprocessor regulates current and voltage for the peltier element depending upon the processed signals and the stored pre-defined reference temperature. The bi-directional communication unit communicates signals between the microprocessor and the computing device. The computing device sends command to the controller to regulate the temperature of the inner vessel. The bottom cover covers the battery and the printed circuit board. Further, the bottom cover attaches to the hollow bracket.

Disclosed is container for modifying temperature of an object on receiving commands from a computing device. The container includes a hollow outer vessel, a hollow inner vessel, a hollow cylindrical bracket, a first temperature sensor, a peltier element, a heat sink, a second temperature sensor, a battery, a printed circuit board, a memory unit, a microprocessor, a bi-directional communication unit, and a bottom cover. The hollow cylindrical bracket is having a first indent, a second indent, a sidewall, and a closed bottom end. The hollow bracket sidewalls move between the second outer surface and the first inner surface. The first temperature sensor measures temperature of the second outer surface of the inner vessel. The memory unit stores pre-defined reference temperature. The microprocessor processes signals received from the first temperature sensor and the second temperature sensor. The microprocessor regulates current and voltage for the peltier element depending upon the processed signals and the stored pre-defined reference temperature. The bi-directional communication unit communicates signals between the microprocessor and the computing device. The computing device sends command to the controller to regulate the temperature of the inner vessel. The bottom cover covers the battery and the printed circuit board. Further, the bottom cover attaches to the hollow bracket.

A heat insulating container is described which can keep a heat insulating state (including cold insulating state) of an inside container stored in an outside container for a long period of time, and improve safety and usability. The heat insulating container may include the outside container having a heat insulating structure; the inside container having a cold insulating structure or a heat insulating structure; and a cover member which is attached to the inside container in a state in which the inside container is stored in the cover member; in which the inside container is stored in the outside container in a non-contact state through the cover member.

A heat insulating container is described which can keep a heat insulating state (including cold insulating state) of an inside container stored in an outside container for a long period of time, and improve safety and usability. The heat insulating container may include the outside container having a heat insulating structure; the inside container having a cold insulating structure or a heat insulating structure; and a cover member which is attached to the inside container in a state in which the inside container is stored in the cover member; in which the inside container is stored in the outside container in a non-contact state through the cover member.

A can end has a public side and an opposing product side. A circumferential curl is located about a center axis and defines an outer perimeter of the can end. A circumferential wall extends downwardly from the curl. A circumferential, generally U-shaped countersink extends radially inwardly from the circumferential wall relative to the center axis and upwardly. A center panel extends radially inwardly from the countersink relative to the center axis and has a displaceable tear panel defined by frangible score and a hinge segment on the public side and a tab fixed to the public side which has a nose portion overlying a portion of the displaceable tear panel. A circumferential panel joins the countersink with the center panel and has a first panel radius joined to a second panel radius by a short wall extending upwardly and inwardly. The circumferential panel has a bead formed therein.

A bottle cap includes a cap body for covering an opening of a bottle. A bottle opener is integrally formed into the cap body for removing a crimped, twist-off or pop-off type cap from another bottle. The cap body includes an outer surface and the bottle opener is formed as a groove in a portion of the outer surface. The bottle cap need not be removed to access the bottle opener and the cap may be removed from another bottle while cap body is covering the opening of its associated bottle.