Abstract: A computer implemented method of operating an information coordination system of a cargo transport system includes entering a proposed delivery task into a remote user interface device. An environmental control assembly of a cargo transport system may be utilized to monitor a product for a specified condition. Condition updates associated with the monitoring may be sent to the remote user interface.

Abstract: A system for managing spoilage of perishable goods including: a storage device to store perishable good requirements, spoilage characteristics, and perishable good parameters associated with the perishable goods; and a spoilage management system coupled to the storage device. The spoilage management system including: a quality assessment module to determine quality levels in response to at least one of the perishable good parameters and the perishable good requirements; a spoilage determination module to determine spoilage risk levels in response to at least one of the perishable good parameters, the spoilage characteristics, and the quality levels; and a meshing module to determine output parameters in response to at least one of the quality levels and the spoilage risk levels.

Abstract: Disclosed is a system for managing power in a transport refrigeration unit (TRU) installed on a trailer, having: a TRU controller configured to perform steps such as: executing a system-level energy manager, wherein the TRU controller: adaptively selects energy flow parameters based on one or more mission specific parameters and TRU power health; executes a predictive analytics module for collecting mission specific parameters and predicting TRU cooling power demands; and executes an online optimization module for generating a power source schedule for the TRU based on the predicted TRU cooling power demands; and operating the TRU according to the generated power source schedule.

Abstract: Disclosed is a system for dynamically mitigating resonance in a transport refrigeration unit (TRU) during a mission, having: a TRU controller configured for operating a TRU engine during the mission according to an operational baseline, and while operating the TRU engine, and contemporaneously performing steps including: obtaining a first set of data that comprises real time measurements from one or more accelerometers installed in the TRU; converting the real measurements to a second set of data that comprises real time shock and vibration data; processing the second set of data in a control loop to determine an updated operational baseline that avoids resonance detected in the first set of data; and operating the TRU engine according to the updated operational baseline.

Abstract: A hybrid transport refrigeration unit includes a high voltage battery, at least one high voltage component, a generator, a combustion engine, and a low voltage starter. The high voltage battery includes a plurality of cells connected to the high voltage component. The generator is configured to provide electric power to at least one of the at least one high voltage component. The combustion engine is constructed and arranged to drive the generator. The low voltage starter is electrically connected to at least one of the plurality of cells, and is constructed and arranged to start the combustion engine.

Abstract: A system for managing sanitation of a container for perishable goods including: a storage device to store perishable good requirements, sanitation schedule parameters, sanitation requirements, sanitation test results, and perishable good parameters associated with the perishable goods; and a sanitation management system coupled to the storage device. The sanitation management system including: a sanitation assessment module to determine sanitation risk levels in response to at least one of the perishable good parameters, the perishable good requirements, the sanitation schedule parameters, sanitation test results, and the sanitation requirements; a sanitation schedule module to determine sanitation schedule adjustments in response to at least one of the sanitation risk level, the sanitation schedule parameters, and the sanitation requirements; and a meshing module to determine output parameters in response to at least one of the sanitation risk levels and the sanitation schedule adjustments.

Abstract: A system for organizing perishable goods including: a storage device (80) to store perishable good requirements (82), loading dock parameters (86), and perishable good parameters (84) associated with the perishable goods; and a loading dock management system (90) coupled to the storage device. The loading dock management system including: a perishable good risk module (92) to determine a perishable good risk level for each perishable good in response to the perishable good parameters and the perishable good requirements; and a loading dock organizational module (94) to determine a loading dock notification in response to the perishable good risk level and the loading dock parameters.

Abstract: A system for monitoring the quality of perishable goods including: a storage device (80) to store consumer feedback (84), consumer preferences (86), and parameters (82) associated with the perishable goods (34); and a quality management system (90) coupled to the storage device. The quality management system including: a cold chain evaluation module (92) to determine quality elements in response to the consumer feedback and the parameters; and a consumer suggestion module (94) to determine perishable good recommendations in response to the parameters, the consumer feedback, and the consumer preferences.

Abstract: A system for determining transportation for perishable goods including: a storage device to store vehicle parameters, user parameters, destination parameters, and perishable good requirements; and a route management system coupled to the storage device. The route management system including: a route determination module to determine potential routes in response to at least one of the vehicle parameters, user parameters, destination parameters, and perishable good requirements; a cost module to determine cost parameters of the perishable goods in response to at least one of the potential routes, user parameters, perishable good requirements, and vehicle parameters; a risk analysis module to determine risk parameters in response to at least one of the potential routes, user parameters, perishable good requirements, and vehicle parameters; and a meshing module to determine output parameters in response to at least one of the potential routes, cost parameters, and risk parameters.

Abstract: A method and system for managing a downstream refrigeration system in response to an upstream refrigeration system includes storing upstream data from the upstream refrigeration system, determining a present goods condition corresponding to the upstream data, determining a desired goods condition corresponding to the present goods condition, determining downstream parameters corresponding to the desired goods condition, and providing the downstream parameters to the downstream refrigeration system.

Abstract: A system for monitoring perishable goods including: a storage device to store perishable good requirements, producer inputs, safety alerts, consumer parameters, and historical quality parameters associated with the perishable goods; a risk management system coupled to the storage device. The risk management system including: a quality determination module to determine quality levels of the perishable goods in response to at least one of the historical quality parameters and perishable good requirements; a risk determination module to determine risk levels of the perishable goods in response to at least one of the historical quality parameters, perishable good requirements, producer inputs, consumer parameters, and safety alerts; and a meshing module to determine output parameters in response to at least one of the quality levels and the risk levels.

Abstract: A transport refrigeration unit controllably cools a container, and includes a compressor (58) constructed and arranged compress a refrigerant and a compressor motor (60) configured to drive the compressor (58). A battery (52) of the unit is configured to at least in-part provide electric power to the compressor motor (60). A power management system of the unit includes a computer-based controller configured to generate diagnostic data from data signals received from a battery temperature sensor (122), a battery current sensor (124), and a compressor motor current sensor (126).

Abstract: A refrigeration unit for a vehicle comprising a condenser configured to be positioned outside of the vehicle, an evaporator in thermal communication with the condenser and configured to be positioned inside of a cargo space of the vehicle, the evaporator having a fan, and a movable directional element housed within the evaporator and deployable from a first position to a second position, wherein in the first position, the movable directional element is stowed within the evaporator and in the second position the movable directional element provides directional airflow control to air being blown by the fan of the evaporator.

Abstract: A transport refrigeration unit (26) includes a compressor (58) constructed and arranged to compress a refrigerant and an electric compressor motor configured to drive the compressor. A generator (54) of the unit is configured to provide electric power to the compressor motor during standard set point conditions, and an energy storage device of the unit is configured to supplement the electric power to the compressor motor during temperature pulldown conditions.

Abstract: A transport refrigeration unit (26) includes a compressor (58) constructed and arranged to compress a refrigerant and a compressor motor (60) configured to drive the compressor (58). A condenser heat exchanger (64) of the unit is operatively coupled to the compressor (58), a condenser fan (66) is configured to provide air flow over the condenser heat exchanger (64), and a condenser fan motor (90) drives the condenser fan (66). An evaporator heat exchanger (76) of the unit is operatively coupled to the compressor (58), an evaporator fan (78) is configured to provide air flow over the evaporator heat exchanger (76), and an evaporator fan motor (98) drives the evaporator fan (78). A combustion engine (56) of the unit drives a generator (54) configured to provide electric power to the compressor motor (60). An energy storage device (52) of the unit is configured to provide electric power to the condenser and evaporator fan motors (90, 98).

Abstract: A vehicle having a wireless power system is provided. The vehicle includes a tractor and a trailer mounted to the tractor, the tractor having a tractor frame and the trailer having a refrigeration unit. A first inductive charging pad is mounted on the trailer, the first inductive charging pad electrically connected to a portion of the refrigeration unit. A second inductive charging pad is mounted on the tractor, the second inductive charging pad electrically connected to a portion of the tractor and configured to induce an electrical current in the first inductive charging pad. The first inductive charging pad and the second inductive charging pad are configured such that the second charging pad can induce and maintain the electric current in the first inductive charging pad throughout a range of relative rotation.

Abstract: An engineless transport refrigeration unit includes a compressor constructed and arranged to compress a refrigerant, and a compressor motor configured to drive the compressor and operate at a voltage range of two hundred (200) to six hundred (600) volts. A battery of the engineless transport refrigeration unit provides the power to the compressor motor.

Abstract: A heating, ventilation, air conditioning and refrigeration (HVAC&R) unit includes an evaporator circulating a flow of refrigerant therethrough to cool a flow of compartment air flowing over the evaporator, and a condenser operably connected to the evaporator to condense the flow of refrigerant therethrough. The evaporator and the condenser are relatively positioned such that a liquid condensate at an exterior of the evaporator is directed by gravity onto an exterior of the condenser to increase an operating capacity of the condenser.

Abstract: A method and system to provide an estimated shelf life value for a product to a user includes at least one information source to provide at least one product information entry for the product, and a shelf life estimation system, including a processor to receive and analyze the at least one product information entry from the at least one information source, and to provide the estimated shelf life value to the user.

Abstract: A transport container for multiple stages of a distribution chain is provided. The transport container includes a power source providing electrical power to the transport container. An ethylene injection unit configured to store and inject ethylene into the transport container. A controller in operative communication with the power source and the ethylene injection unit. The controller is configured to command the ethylene injection unit to inject ethylene into the transport container along the multiple stages of the distribution chain.