A tool for securing a shipping container head with two extensions extending away from the head and having a space between them sufficient to accommodate a bar bracket of a container lashing turnbuckles used to secure a shipping container door. The head also has a handle that can function as a lever, so that when the tool engages the turnbuckle bar bracket, an operator can close and secure the shipping container door.

A system. The system includes a liquid container and an energy absorbing system positioned. The liquid container includes a wall which defines an interior volume of the liquid container. The energy absorbing system is within an interior volume of the liquid container. The energy absorbing system is configured such that if an object passes through the wall of the liquid container and impacts the energy absorbing system, an amount of energy absorbed by the energy absorbing system is at least 18% greater than an amount of energy absorbed by the wall of the liquid container. The energy absorbing system includes one or more energy absorbing members, wherein at least one of the one or more energy absorbing members comprises a metal and has a Brinell hardness of at least 150.

A system. The system includes a liquid container and an energy absorbing system positioned. The liquid container includes a wall which defines an interior volume of the liquid container. The energy absorbing system is within an interior volume of the liquid container. The energy absorbing system is configured such that if an object passes through the wall of the liquid container and impacts the energy absorbing system, an amount of energy absorbed by the energy absorbing system is at least 18% greater than an amount of energy absorbed by the wall of the liquid container. The energy absorbing system includes one or more energy absorbing members, wherein at least one of the one or more energy absorbing members comprises a metal and has a Brinell hardness of at least 150.

Systems for enhanced detection and response to an environmental anomaly in a shipping container may include wireless ID nodes within a shipping container, and a command node mounted to the container that communicates with the ID nodes and a transit vehicle transceiver. The command node's memory has program code, a communication profile and context data for each the ID nodes. The command node is adapted to monitor the ID nodes for an unanticipated ceased broadcasting from any of the ID nodes per the communication profiles; detect the anomaly when the number of ID nodes in the unanticipated ceased broadcasting state exceeds a threshold setting on the command node; generate a layered alert notification identifying a mediation recipient and mediation action, and establishing a mediation response priority based upon the ceased broadcasting ID nodes; and initiate the mediation response by transmitting the notification to the external transceiver.

Adaptive wireless node-implemented systems and methods are described for detecting an environmental anomaly related to a shipping container and reporting a layered alert notification to an external transceiver on a transit vehicle transporting the shipping container. The system has ID nodes within the container (a portion of which being associated with objects transported in the container), a primary command node within the container, and a designated survivor command node mounted to the container. The primary command node monitors signal activity from the ID nodes, identifies the environmental anomaly based upon the signal activity, generates the alert notification (identifying a targeted mediation recipient and mediation action, and establishing a mediation response priority), and transmits the alert notification to the external transceiver to initiate a mediation response. The designated survivor command node takes over as the primary command node when unable to communicate with the primary command node.

An enhanced shipping container apparatus that maintains packages is described having integrated fire suppression. The apparatus has a container base supporting the packages, multiple container walls coupled to the container base, and a container top coupled to each of the container walls. A fire suppression panel is integrated as part of one or more of the walls and top portion, and has a support sheet of fire resistant material; an interior exposed sheet of temperature sensitive material; a sealed boundary connecting the support sheet and interior exposed sheet on peripheral edges (where the sealed boundary, support sheet and interior exposed sheet define a holding cavity), and integrated fire suppression material in the holding cavity. The temperature sensitive material of the interior exposed sheet releases the integrated fire suppressant material from within the holding cavity when the temperature sensitive material of the interior exposed sheet is exposed to a threshold temperature.

An enhanced shipping container apparatus that maintains packages is described having integrated fire suppression. The apparatus has a container base supporting the packages, multiple container walls coupled to the container base, and a container top coupled to each of the container walls. A fire suppression panel is integrated as part of one or more of the walls and top portion, and has a support sheet of fire resistant material; an interior exposed sheet of temperature sensitive material; a sealed boundary connecting the support sheet and interior exposed sheet on peripheral edges (where the sealed boundary, support sheet and interior exposed sheet define a holding cavity), and integrated fire suppression material in the holding cavity. The temperature sensitive material of the interior exposed sheet releases the integrated fire suppressant material from within the holding cavity when the temperature sensitive material of the interior exposed sheet is exposed to a threshold temperature.

Systems and method are described for detecting and responding to an environmental anomaly in a shipping container transported by a transit vehicle having an onboard fire suppression system. Systems generally have a set of ID nodes within the container and another set outside the container, and a command node mounted to the container. The command node's processor is programmed to monitor both sets of ID nodes per their respective ID node communication profiles for unanticipated cessation of ID node broadcasting, detect an unresponsive group of ID nodes based on the monitoring, determining if the group includes ID nodes from which set of ID nodes, identifying the anomaly when the unresponsive group's size exceeds a threshold setting, generate an alert notification, and transmit the alert notification to the external transceiver or the fire suppression system directly based on an alert level setting so as to initiate different levels of mediation response.

An enhanced shipping container apparatus generally includes a shipping container housing, sensor-based ID nodes in different locations on the housing, and a command node mounted to the housing. The ID nodes have environmental sensors that generate sensor data on an environmental condition proximate each respective ID node. The command node is programmatically configured to detect sensor data broadcasted from the ID nodes; identify an environmental anomaly for the shipping container when the detected sensor data does not include sensor data from a threshold number of ID nodes and when sensor data detected indicates an environmental condition exceeding an environmental threshold; and initiate a mediation response related to a targeted mediation action (identified by the command node) by transmitting a layered alert notification to an external transceiver.

A node-enabled battery system having integrated environmental detection and reporting. The system may have a battery and sensor-based node attached to the battery. The system's sensor-based node has a processor, memory (maintaining a battery monitoring program code and a battery threshold metric value), a wireless communication interface and a sensor operative to sense a battery status condition for the battery. When executing the battery monitoring program code, the processor is programmatically configured and adapted to be operative to receive status data from the sensor reflecting the battery status condition as sensed by the sensor, automatically trigger generation of a layered alert notification related to the battery when the received status data is inconsistent with the battery threshold metric value, and cause the wireless communication interface to broadcast the layered alert notification to initiate a mediation response related to the battery status condition for the battery.