A method for verifying an alarm condition in an environmental sensing system includes monitoring data received from environmental sensors; detecting anomalous data received from one of the plurality of environmental sensors; determining the context in which the anomalous data was acquired is consistent with typical usage activities; and providing an alarm condition alert when the determined context is not consistent with typical activities. A system for intelligently monitoring environmental conditions includes environmental sensors configured to monitor first and second environmental conditions and to communicate with an intelligent analysis module. The intelligent analysis module is configured with logic to determine whether anomalous data has been collected by the environmental sensors, to determine the context in which the anomalous data was collected, to determine whether the anomalous data can be attributed to a routine activity, and to provide an alarm condition if the anomalous data cannot be attributed to a routine activity.

Automated blast gel pack conditioning equipment is provided and includes a housing with an evaporator and heater and defining a void space for containing a set of gel packs, at least one fan for circulating air within the housing such that a path of air flow extends through an air insufflation end to an air return end within the housing, at least one temperature sensor located within the housing, and a controller for receiving temperature measurements from the at least one temperature sensor and for automatically controlling operation of the evaporator, heater, and fans during phase change processing and conditioning of gel packs. A method of phase change processing and conditioning gel packs and a temperature sensor assembly are also provided.

A freezer includes a plurality of evaporators coupled to a payload bay with a multiplicity of coolant tubes in each evaporator, wherein each tube enters and then exits the payload bay, further comprising one or more cryogenic valves coupled to the coolant tubes; a pump to force coolant flowing through the evaporators; sensors coupled to the evaporators of the freezer to monitor vital parameters of the freezer; a processor; a wireless telemetry system to communicate one or more measured characteristics of the freezer in accordance with a service level agreement to a remote computer; and at least one notification component that provides a notification associated with a specific customer responsive to the measured characteristic of the service crossing a pre-defined threshold.

A refrigerating appliance includes a cabinet that defines an interior cavity. A temperature sensing network monitors a temperature stratification of the interior cavity. The temperature stratification includes a plurality of temperature levels that correspond to respective locations of the interior cavity. A controller is configured to receive an input related to an item to be stored. The controller is further configured to compare the input with the temperature stratification. The controller is further configured to identify a primary storage location of the item to be stored based upon a comparison of the input and the plurality of temperature levels of the temperature stratification. A visual indicia is disposed within the interior cavity and coupled to the controller. The visual indicia activates to identify the primary storage location of the item to be stored.

A refrigerator appliance includes a cabinet defining multiple food storage chambers which are operable at distinct temperatures. The refrigerator appliance includes a cabinet comprising a plurality of insulated mullions. The insulated mullions at least partially define a fresh food chamber, a freezer chamber, a convertible chamber, and a plenum. The refrigerator appliance also includes a first damper selectively providing fluid communication between the fresh food chamber and the plenum, a second damper selectively providing fluid communication between the freezer chamber and the plenum, and a fan disposed between the convertible chamber and the plenum. The fan is configured to force air from the plenum into the convertible chamber.

A refrigeration device includes a thermal transfer unit with an evaporative region, an adiabatic region, and a condensing region with a reversible valve attached to the adiabatic region. The device includes a container sealed around PCM, with a set of refrigeration coils of a compressor unit in thermal contact with the PCM. A storage region is in thermal contact with the evaporative region of the thermal transfer unit. A controller is operably connected to the reversible valve and the refrigeration compressor unit. The storage region can be used to store cold packs within a predetermined temperature range for medical outreach.

A method of controlling a refrigerator includes operating a cool air supply to output cool air for cooling a storage compartment, obtaining a result value based on a temperature value sensed by a temperature sensor during a first reference time interval, obtaining a plurality of result values during a second reference time interval, determining a representative temperature of the storage compartment among the obtained plurality of result values, determining an output of the cool air supply based on the representative temperature, and operating the cool air supply at the determined output.

The subject matter of this specification can be embodied in, among other things, a method for time shifting when a cold storage facility is cooled that includes determining a thermal model of a cold storage facility, obtaining an energy cost model that describes a schedule of variable energy costs over a predetermined period of time in the future, determining an operational schedule for at least a portion of a refrigeration system based on the thermal model, the energy cost model, and a maximum allowed temperature, and powering on the portion the refrigeration system based on the operational schedule, cooling, by the powered portion of the refrigeration system to a temperature below the maximum allowed temperature, reducing power usage of the powered portion of the refrigeration system based on the operational schedule, and permitting the facility to be warmed by ambient temperatures toward the maximum allowed temperature.

The present invention provides a system and apparatus for monitoring temperature and airflow from multiple sensors node for maintaining proper conditions within a refrigerated tractor-trailer unit or reefer. The system provides a mesh network of multiple sensors, which communicate between sensors and with a processing unit of a reefer unit for monitoring the condition of transported goods.

A method for verifying an alarm condition in an environmental sensing system includes monitoring data received from environmental sensors; detecting anomalous data received from one of the plurality of environmental sensors; determining the context in which the anomalous data was acquired is consistent with typical usage activities; and providing an alarm condition alert when the determined context is not consistent with typical activities. A system for intelligently monitoring environmental conditions includes environmental sensors configured to monitor first and second environmental conditions and to communicate with an intelligent analysis module. The intelligent analysis module is configured with logic to determine whether anomalous data has been collected by the environmental sensors, to determine the context in which the anomalous data was collected, to determine whether the anomalous data can be attributed to a routine activity, and to provide an alarm condition if the anomalous data cannot be attributed to a routine activity.