A heat patch includes a dressing layer, a release layer, an adherence layer, and a heating layer. The dressing layer is combined with the release layer and the adherence layer. The heating layer is combined with the adherence layer. When the dressing layer is adhered to the user skin, the heating structure of the heating layer generates the heat which is transmitted to the dressing layer for achieving a hot compressing function.

A heat patch includes a dressing layer, a release layer, an adherence layer, and a heating layer. The dressing layer is combined with the release layer and the adherence layer. The heating layer is combined with the adherence layer. When the dressing layer is adhered to the user skin, the heating structure of the heating layer generates the heat which is transmitted to the dressing layer for achieving a hot compressing function.

Provided is a thermotherapy device, which includes a first housing (10), a second housing (20) disposed under the first housing (10), a transfer plate (30), at both sides of which transfer rollers (31) are provided, and a pair of guide rails (40) that is provided to the second housing (20) and on which the respective transfer rollers (31) of the transfer plate (30) are placed. The pair of guide rails (40) are integrally molded when the second housing (20) is injection-molded. Thus, since the guide rails on which the transfer rollers of the transfer plate travel are integrally molded when the second housing is injection-molded, inefficiency caused by mounting separate rails as in the related art is removed, and thereby assemblability, productivity, and economic efficiency of the thermotherapy device can be improved.

An exothermic natural massage shell includes a natural bivalve shell comprising a first half and a second half adhered together with an adhesive to form a hollow chamber. An aperture is formed in the first half to provide a portal to the hollow chamber of the bivalve shell. A reactant is disposed inside the hollow chamber of the bivalve shell. The reactant may be a reactive powder mixture disposed inside a fluid-permeable pouch. Combining the reactant with an activator inside the hollow chamber of the bivalve shell causes an exothermic reaction that heats the bivalve shell and maintains the bivalve shell at a substantially constant elevated temperature for a duration of time. The adhesive adhering the first shell half to the second shell half includes a first elastomeric polymer bonding agent with balanced coefficient of expansion properties and a second flexible resin sealant that makes the adhesive moisture-proof.

An exothermic natural massage shell includes a natural bivalve shell comprising a first half and a second half adhered together with an adhesive to form a hollow chamber. An aperture is formed in the first half to provide a portal to the hollow chamber of the bivalve shell. A reactant is disposed inside the hollow chamber of the bivalve shell. The reactant may be a reactive powder mixture disposed inside a fluid-permeable pouch. Combining the reactant with an activator inside the hollow chamber of the bivalve shell causes an exothermic reaction that heats the bivalve shell and maintains the bivalve shell at a substantially constant elevated temperature for a duration of time. The adhesive adhering the first shell half to the second shell half includes a first elastomeric polymer bonding agent with balanced coefficient of expansion properties and a second flexible resin sealant that makes the adhesive moisture-proof.

The following description relates generally to self-heated consumer spa products heated by means of a prolonged exothermic chemical reaction for various therapeutic and/or spa applications for applying heat to portions of a person's body.

The following description relates generally to self-heated consumer spa products heated by means of a prolonged exothermic chemical reaction for various therapeutic and/or spa applications for applying heat to portions of a person's body.

The current invention discloses a treatment device having a heat source, a power source, a heat applicator and a lighting mechanism. The power source includes at least one battery having superior properties such as prolonged electricity production and prompt recharging. The heat applicator includes a heat conductive layer made from nanofibers, providing highly efficient heat distribution to the targeted regions. The lighting mechanism employs light emitting nano fibers to treat targeted regions. The power source provides energy to the light source, which generates light so that the applicator may distribute to an injury site or wound bed of a user. The heat source may be an exothermic chemical reaction designed to last for several hours supplying heat to the treatment device or an electronically produced heat. The treatment device further comprises a plurality of electrodes for electrical stimulation treatment.

The current invention discloses a treatment device having a heat source, a power source, a heat applicator and a lighting mechanism. The power source includes at least one battery having superior properties such as prolonged electricity production and prompt recharging. The heat applicator includes a heat conductive layer made from nanofibers, providing highly efficient heat distribution to the targeted regions. The lighting mechanism employs light emitting nano fibers to treat targeted regions. The power source provides energy to the light source, which generates light so that the applicator may distribute to an injury site or wound bed of a user. The heat source may be an exothermic chemical reaction designed to last for several hours supplying heat to the treatment device or an electronically produced heat. The treatment device further comprises a plurality of electrodes for electrical stimulation treatment.

The present disclosure describes a treatment device having a heat source, a power source, a heat applicator and a lighting mechanism. The power source includes at least one battery having superior properties such as prolonged electricity production and prompt recharging. The heat applicator includes a heat conductive layer made from nanofibers, providing highly efficient heat distribution to the targeted regions. The lighting mechanism employs light emitting nano fibers to treat targeted regions. The power source provides energy to the light source, which generates light so that the applicator may distribute to an injury site or wound bed of a user. The heat source may be an exothermic chemical reaction designed to last for several hours supplying heat to the treatment device or an electronically produced heat. The treatment device further comprises a plurality of electrodes for electrical stimulation treatment.