A hydrocarbon fluid storage structure has a storage vessel containing hydrocarbon fluids therein and a containment vessel fully surrounding the storage vessel so as to provide secondary containment to the storage vessel. A heater is surrounded by heat exchanger fluid within a heat exchanger vessel within the storage vessel. The exterior of the containment vessel is insulated. The heat exchanger fluid is passively circulated within a closed loop path defined by the heat exchanger vessel. Connecting valves providing external access to the contents of the storage vessel are received within a valve housing in heat exchanging relation with a containment space between the containment vessel and the storage vessel.

The invention relates to a diffuser guide construction for evening the flow of bulk material in a bulk material container, wherein the diffuser guide construction is formed by at least one central tube which is either open at the top and tapers upwards or is closed at the top. The invention also relates to a bulk material container comprising such a diffuser guide construction and the use of a diffuser guide construction for evening a flow of bulk material.

A hatch device comprised by a main support body, a flow guide piece and an optional plug, which allows for minimum modifications in the service hatch cover's structure during installation.

An energy storage system includes a DC bus; a plurality of battery strings, each battery string comprising batteries coupled electrically together; a plurality of DC/DC converters electrically coupling respective battery strings to the DC bus; an enclosure housing the battery strings and the DC/DC converters; and a temperature control system. The temperature control system includes at least one heating, ventilation, and air conditioning (HVAC) system, and a controller. The controller is programmed to execute a method of predicting heat loads for respective battery strings within the enclosure, wherein the heat loads comprise external heat loads and internal heat loads; determining one or both of DC/DC converter operating commands and HVAC operating commands based on the respective predicted heat loads to control the actual heat loads of the respective battery strings; and operating one or both of the DC/DC converter and the HVAC system in response to at least one of the DC/DC converter operating commands and the HVAC operating commands.

An energy storage system includes a DC bus; a plurality of battery strings, each battery string comprising batteries coupled electrically together; a plurality of DC/DC converters electrically coupling respective battery strings to the DC bus; an enclosure housing the battery strings and the DC/DC converters; and a temperature control system. The temperature control system includes at least one heating, ventilation, and air conditioning (HVAC) system, and a controller. The controller is programmed to execute a method of predicting heat loads for respective battery strings within the enclosure, wherein the heat loads comprise external heat loads and internal heat loads; determining one or both of DC/DC converter operating commands and HVAC operating commands based on the respective predicted heat loads to control the actual heat loads of the respective battery strings; and operating one or both of the DC/DC converter and the HVAC system in response to at least one of the DC/DC converter operating commands and the HVAC operating commands.

The invention is for a heating pad for a container to lie against at least one external surface of the container, and apply thermal energy to the container, and any material therein, when needed. The pad consists of a foamed resilient substrate with a first presenting major surface substantially equal in area to the at least one external surface of the container. A heating cable is located on the first presenting major surface to form an electrical circuit that when energised provides the thermal energy. A planar sheet material is above the first presenting major surface, and below a second presenting major surface of the substrate, the planar sheet material extends past the first and second presenting major surfaces and sealed at a periphery to form an encapsulation of the substrate and heating cable. There is an electrical connection from the heating cable internally of the encapsulation to external of the encapsulation. Such that the heating pad can be located against the at least one external surface of the container to move with that container, and when connected to a source of electricity can supply thermal energy to the container and any material contained therein.

The present disclosure relates to a unit load device and a method for storing and transporting articles. The unit load device includes: a housing defining an internal space and an opening to the internal space; and a cover configured to operably open or hermetically close the opening; wherein the housing is provided with a housing temperature control layer containing at least a first phase change material, and/or the cover is provided with a cover temperature control layer containing at least a second phase change material, so that during storage of articles in the internal space hermetically closed by the cover, a temperature of the internal space is within a preset temperature range after a preset period of time has elapsed.

A releasable power assembly prevents damage to plugs and receptacles connected to refrigerated shipping containers (reefers). Reefers are temporarily stored in shipping port reefer scaffolds and then loaded onto or unloaded off of ground transportation or freighters. However, errors in port command and control systems may result in the failure to unplug reefers prior to loading or unloading. Conventional reefer power plugs and receptacles are twist-locked together and damaged or destroyed if not manually disconnected prior to reefer movement. An advantageous releasable power assembly automatically unlatches before reaching a breaking point for failure to disconnect plug and receptacle.

A releasable power assembly prevents damage to plugs and receptacles connected to refrigerated shipping containers (reefers). Reefers are temporarily stored in shipping port reefer scaffolds and then loaded onto or unloaded off of ground transportation or freighters. However, errors in port command and control systems may result in the failure to unplug reefers prior to loading or unloading. Conventional reefer power plugs and receptacles are twist-locked together and damaged or destroyed if not manually disconnected prior to reefer movement. An advantageous releasable power assembly automatically unlatches before reaching a breaking point for failure to disconnect plug and receptacle.

A hopper bottom a grain bin above a foundation includes a conical wall tapering inwardly to a bottom discharge opening. An outer cylindrical wall is joined to the top peripheral edge of the conical wall. Upright support legs are connected to the outer wall for supporting the cylindrical grain bin walls thereabove. A bottom wall is connected radially between the outer wall and the conical wall so as to define a manifold passage bounded by the conical wall, the outer wall and the bottom wall which is generally annular in shape and which is located externally of the conical wall. Vent openings are formed in the conical wall to receive aeration air from a blower connected to the manifold passage. A cover member is supported above the vent openings in the conical wall in connection with the outer wall above the conical wall to prevent material entering the vent openings.