An apparatus is disclosed. The apparatus includes a resistive wire having a circumference. The apparatus further includes a first fiberglass layer disposed about the circumference of the resistive wire and along a length of the resistive wire. The apparatus further includes a second fiberglass layer. The apparatus further includes a third fiberglass layer, the second fiberglass layer disposed between the first fiberglass layer and the third fiberglass layer, the third fiberglass layer forming an outer layer and surrounding the second fiberglass layer.

A temperature control system for a refrigerator. The temperature control system is positioned in a refrigerated compartment and fluidly communicates with a cooling fan. The temperature control system includes a vertical partition having a front surface and a rear surface. The rear surface faces a rear wall of the refrigerated compartment and the front surface faces an open end of the refrigerated compartment. An air passage is formed in the vertical partition extending from a lower portion of the vertical partition to an upper portion of the vertical partition. A heater assembly is disposed between the front surface and the rear surface of the vertical partition proximate the air passage wherein air conveyed along the air passage is heated by the heater assembly when the heater assembly is energized.

A refrigerator appliance or sanitizer assembly may include a heating plate and a storage container. The heating plate may be mounted on a door of the refrigerator appliance. The storage container may be disposed on the heating plate and extend between a bottom end and a top end. The storage container may define a sanitization chamber above the heating plate and a container opening at the top end to permit access to the sanitization chamber.

A refrigerator includes an ice tray, a motor, an ejector including a rotary shaft and a protrusion pin, and a heater for selectively supplying heat to the ice tray. A control method of the refrigerator includes a first step of sensing whether the ejector is rotated to reach a first setup position; a second step of driving the heater and stopping driving of an ice making compartment fan if the first step is satisfied; a third step of determining whether the ejector is rotated to reach a second setup position; and a fourth step of stopping driving of the heater if the third step is satisfied, and wherein the ejector continues to be rotated while the second to fourth steps are implemented.

A cryogenic cooling manifold and methods incorporating a cryogenic cooling manifold for managing the gas layer(s) above a liquid cryogen to control cooling temperature-time profiles and ice formation for microliter and smaller samples that are plunged through the gas and into the liquid cryogen.

A refrigerator and a control method of the same are disclosed, wherein the refrigerator comprises an ice tray for receiving water to generate ices; a motor capable of being rotated in a forward or reverse direction; an ejector including a rotary shaft rotating the ices made in the ice tray to discharge the ices from the ice tray, rotated by being axially connected to the motor, and a protrusion pin protruded in a radius direction of the rotary shaft to adjoin the ices; a heater for selectively supplying heat to the ice tray; a door switching sensor for sensing a storage compartment door's opening or closing, the storage compartment door being provided with the ejector; and a controller for turning the heater on or off in accordance with a rotation position of the ejector.

A side-by-side refrigerator system includes a first refrigerated cabinet and a second refrigerated cabinet alongside the first refrigerated cabinet. A heater is positioned within a wall of one of the first refrigerated cabinet and the second refrigerated cabinet. A controller is configured to constantly operate the heater during a side-by-side operating mode. The controller is disposed within the one of the first refrigerated cabinet and the second refrigerated cabinet.

A refrigerator according to an embodiment of the present disclosure includes a first storage compartment, a cavity, a heat source, a cold source, a water molecule freezing preventing device, and a controller configured to control an output of at least one of the heat source, the cold source, or the water molecule freezing preventing device, wherein the controller is configured to perform a first operation step to operate based on the first notch temperature for a cooling operation, a second operation step to operate based on a second notch temperature for a heating operation, and a third operation step to operate based on a third notch temperature for the cooling operation, the second notch temperature is higher than 0° C., and the third notch temperature is higher than the first notch temperature. Accordingly, it is possible to efficiently supply the cold or heat until reaching a supercooling maintenance section.

A method for reducing sweating in a temperature-controlled display device includes receiving values of an ambient temperature, a door frame temperature, and relative humidity. The method can also include estimating a value of a dewpoint temperature using the values of the ambient temperature and the relative humidity. The method can also include determining control decisions for a door frame heater of the temperature-controlled display device using the value of the dewpoint temperature and the door frame temperature, and transitioning the door frame heater between an on-state and an off-state using the control decisions to maintain the value of the door frame temperature at or above the value of the dewpoint temperature.

Embodiments of a freeze dry shelf may include a body, a surface layer, and a component, the body may have a planar monolithic form. The surface layer may be applied to a portion of the body. The component may be disposed on a planar geometry of the body to detect a measurement of a condition proximate the body and communicate a signal indicative of the parameter via a contact disposed on an edge of the body.