Fibers, fabrics, mattresses and processes of making the fibers generally include a microencapsulated phase change material; and a polymer, wherein the microencapsulated phase change material is greater than 50 percent by weight of the fiber. The process for making the fibers is a dry jet/wet spinning process free of sonication.

The present invention relates to a heated blanket for use on a boat. The blanket has a top layer which is nylon, and a bottom layer which is fleece. There are one or more heater hose inserts (or openings) on each side and one or more foot pockets. The one or more heater hose inserts may be inserted with one or more heater hoses of a boat. The one or more heater hoses may blow in hot air. The hot air fills in the blanket, thereby warming the surrounding environment, which in turn warms the user body who is using the blanket. The blanket prevents the loss of body heat while utilizing the on-board heater hose to keep the user warm.

A bedding system, method and kit for the automation and ventilation of an existing duvet are disclosed. The system has an inflatable lining configured to be inserted and affixed into a cover together with the duvet, the inflatable lining comprising a network of pneumatic chambers defining a plurality of openings extending through the lining allowing air to circulate through the lining; and an air blower operatively connected to the inflatable lining for blowing air into the network of pneumatic chambers, so as in use, the inflatable lining is inflated to allow for the duvet and its cover to be straightened back into position after every use of the bed. The system can also include a sub-network for providing warm or cold air to control the temperature of the bedding. In contrast to traditional systems, the proposed invention is light weight and easily adaptable to current commercially available beds.

A temperature modulation system for a bed, blanket, or other furniture includes a fluid for moderating temperature change, a number of conduit circuits for directing the fluid through respective zones, a control unit including a thermoelectric device for modulating temperature of the fluid, and a pump. Each of the conduit circuits selectively and independently directs fluid through its respective zone in order to produce a temperature within the zone that is independent of the temperature outside the zone. The system also includes an arrangement of one or more zones in an arrangement in which the control unit is programmed to vary the zone temperature over time according to a schedule.

This disclosure relates to an auto run mode for initiating a heating cycle of a heated bedding product. A heated bedding product can include a bedding product body comprising a heating element and a controller electrically connected to the heating element. The controller can include a processing circuit, such as a microcontroller, that is configured to operate in an auto run mode in which a heating cycle of the heating element is automatically initiated in response to alternating current power being provided to the controller.

A heating blanket that includes: a first heating segment comprising a first heating section and a first sensing section, the first heating section comprises one or more heating elements and the first sensing section comprises one or more sensing elements; a second heating segment comprising a second heating section, the second heating section comprises one or more heating elements; the first sensing section overlaps the second heating section and the one or more sensing elements in the first sensing section monitor or determine an amount of heat generated by the one or more heating elements in the second heating section.

A self-heating warming blanket includes a pliable outer shell forming a liquid impermeable enclosure. A heat generation layer disposed inside the enclosure has a plurality of liquid permeable heater compartments containing an exothermic reactant. The blanket also has a heater activation system including a sealed bladder containing an activator liquid inside the enclosure. An activation strip extends from outside the outer shell into the enclosure. One segment of the strip is an unsealing segment connected to the bladder. Another segment of the strip is a handle segment outside the outer shell. Pulling on the handle segment opens the bladder and releases the activator liquid into the enclosure where at least a portion of it permeates at least one heater compartment and combines with the exothermic reactant contained therein to initiate an exothermic chemical reaction that heats the warming blanket.

Warming blankets are provided, in which the warming blankets include (i) a perspiration absorptive layer (PAL); (ii) a metal coating layer (MCL); and (iii) a transparent coating layer (TCL); wherein the MCL is located directly or indirectly between the PAL and the TCL. Methods of producing a warming blanket are also provided.

Warming blankets are provided, in which the warming blankets include (i) a perspiration absorptive layer (PAL); (ii) a metal coating layer (MCL); and (iii) a thermal absorptive layer (TAL); wherein the MCL is located directly or indirectly between the PAL and the TAL. Methods of producing a warming blanket are also provided.

A bed covering system adapted to be used by a user to stay comfortable during sleep. The bed covering system includes a blanket and a pillowcase. The blanket has different heat retention zones of at least one section of heavy material and at least one section of lighter material. The heavy material is of material that retains body heat of the user. The lighter material is of a material that allows the escape of body heat of the user and allows circulation of body heat of the user. The heavy material has a higher weave count to trap and retain heat, and the lighter material is of thinner materials that permits more evaporation from a body of a user than the heavy material.