The present invention is directed to a sewing basket for storing thread, pins, needles, scissors, buttons, snaps, measuring tapes, and other sewing tools and accessories. The present invention is further directed to a novel method of collapsing the size of the sewing basket for shipping, storage, and other purposes. The sewing basket of this invention includes a base, an upper frame and a collapsible side walls connecting the base and the upper frame. The basket may switch from a collapsed position with the side walls collapsed bringing the upper frame in proximity to the base and an extended position where the side walls are maintained in an extended position with a support.

The present invention is directed to a sewing basket for storing thread, pins, needles, scissors, buttons, snaps, measuring tapes, and other sewing tools and accessories. The present invention is further directed to a novel method of collapsing the size of the sewing basket for shipping, storage, and other purposes. The sewing basket of this invention includes a base, an upper frame and a collapsible side walls connecting the base and the upper frame. The basket may switch from a collapsed position with the side walls collapsed bringing the upper frame in proximity to the base and an extended position where the side walls are maintained in an extended position with a support.

A hot melt adhesive supply system is disclosed. The hot melt adhesive supply system includes an outer container defining an upper cavity and a lower cavity. The upper cavity includes an inner container having a top opening to receive unmelted hot melt adhesive pieces and a bottom aperture. The system also includes a dispensing mechanism between the upper cavity and the lower cavity. The dispensing mechanism regulates the dispensing of the unmelted hot melt adhesive pieces from the upper cavity to the lower cavity. The dispensing mechanism includes a base plate and one or more rotating members that rotate to move the unmelted hot melt adhesive pieces through a gap defined between the base plate and the bottom aperture. The system also includes a transfer conduit that communicates the unmelted hot melt adhesive pieces from the lower cavity to a hot melt adhesive melter.

A hot melt adhesive supply system is disclosed. The hot melt adhesive supply system includes an outer container defining an upper cavity and a lower cavity. The upper cavity includes an inner container having a top opening to receive unmelted hot melt adhesive pieces and a bottom aperture. The system also includes a dispensing mechanism between the upper cavity and the lower cavity. The dispensing mechanism regulates the dispensing of the unmelted hot melt adhesive pieces from the upper cavity to the lower cavity. The dispensing mechanism includes a base plate and one or more rotating members that rotate to move the unmelted hot melt adhesive pieces through a gap defined between the base plate and the bottom aperture. The system also includes a transfer conduit that communicates the unmelted hot melt adhesive pieces from the lower cavity to a hot melt adhesive melter.

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.

The disclosure provides a packaging container and a packaging method using the same. The packaging container comprises a container body and further comprises: a receiving channel structure formed on an inner side wall of the container body; and a spacer block structure which is configured to be engaged with the receiving channel structure and a position of which within the receiving channel structure is variable to adjust an internal space of the container body. The receiving channel structure and the spacer block structure are provided within the container body of the packaging container according to the disclosure, and the internal space of the container body can be adjusted by changing the position of the spacer block structure within the receiving channel structure, such that the container body can be used to package the products having different sizes.

A container system for use with a cosmetic mask that allows the cosmetic mask to be treated with a liquid personal care preparation just prior to using the mask. The container system comprises a container (1), a closure (2) and a strainer (3). When the container is in an upright position, a flowable product (P) in the reservoir does not reach to the level of the strainer. The invention includes a kit comprising a container system as described herein, and a set of dry cosmetic masks that have not been exposed to the flowable product (P).

A container system for use with a cosmetic mask that allows the cosmetic mask to be treated with a liquid personal care preparation just prior to using the mask. The container system comprises a container (1), a closure (2) and a strainer (3). When the container is in an upright position, a flowable product (P) in the reservoir does not reach to the level of the strainer. The invention includes a kit comprising a container system as described herein, and a set of dry cosmetic masks that have not been exposed to the flowable product (P).