The present disclosure provides an embedded mounting assembly for mounting a large component (e.g., a refrigeration unit) to a cargo vehicle. The mounting assembly includes a mounting insert embedded within a wall of the cargo vehicle to support the loading of the large component while providing for cost-effective manufacturing and installation without reduction of structural integrity and safety.

The present disclosure provides an embedded mounting assembly for mounting a large component (e.g., a refrigeration unit) to a cargo vehicle. The mounting assembly includes a mounting insert embedded within a wall of the cargo vehicle to support the loading of the large component while providing for cost-effective manufacturing and installation without reduction of structural integrity and safety.

Examples provide a system for a temperature-controlled receiving tunnel. A main body includes an interior compartment and a set of adjustable bulkheads configured to create a set of temperature-controlled zones within the interior compartment. A set of cooling devices are configured to adjust an internal temperature of the set of temperature-controlled zones within the interior compartment. A control device analyzes dynamic truck delivery data and ambient temperature data to generate a predicted cooling time and a cooling initiation time. The predicted cooling time comprises an estimated quantity of time after the cooling initiation time to reach a target temperature within a selected zone in the set of temperature-controlled zones.

A system for transporting and installing a cured-in-place-pipe (CIPP) liner to line existing pipe includes a chassis, a bed supported by the chassis and wheels mounted on the chassis for supporting the chassis as it is moved over the road. A container supported by the chassis has a first compartment and a second compartment. A refrigeration system supported by the chassis is operable to keep the first compartment cooled to a temperature at which resin carried within the liner does not prematurely cure. The second compartment contains a powered feeder that can pull liner from the first compartment through a port and feed it out of the container for installation. A method is also disclosed.

This application describes systems, devices, computer readable media, and methods for the function and operation of robotic carts. A robotic cart may include a base component configured for the receipt of a payload, a battery unit, and a mobility apparatus. The robotic cart may include a handlebar component coupled with the base component. The handlebar unit may include a sensor unit configured to transmit a hand detection message when the handlebar unit is grasped by one or more hands and to transmit a force direction message indicating a two-dimensional direction associated with a directional force applied by one or more hands. The robotic cart may be configured to map the area around it and to autonomously move the robotic cart along a path to perform a task.

A method for power and load management of a transport climate control system using a vehicle electrical system is provided. The method includes a controller determining a power draw of the transport climate control load network, determining an amount of power available from the vehicle electrical system, and determining whether the power draw of the transport climate control load network exceeds the amount of power available from the vehicle electrical system. Also, the method includes shedding one or more loads of the transport climate control load network to reduce the power draw of the transport climate control load network until the power draw of the transport climate control load network matches the power available from the vehicle electrical system. Further, the method includes supplying power from the vehicle electrical system to the transport climate control load network.

A method for power and load management of a transport climate control system using a vehicle electrical system is provided. The method includes a controller determining a power draw of the transport climate control load network, determining an amount of power available from the vehicle electrical system, and determining whether the power draw of the transport climate control load network exceeds the amount of power available from the vehicle electrical system. Also, the method includes shedding one or more loads of the transport climate control load network to reduce the power draw of the transport climate control load network until the power draw of the transport climate control load network matches the power available from the vehicle electrical system. Further, the method includes supplying power from the vehicle electrical system to the transport climate control load network.

A method of manufacturing a transport refrigeration unit is provided. The method includes providing an enclosure including an outer layer and a supporter. Providing the enclosure includes supplying one of a first material and a second material to a mold. This also includes supplying the other of the first material and the second material on the one of the first material and the second material that is supplied to the mold. Also, this includes curing the first material and the second material integrally that are supplied to the mold. The first material forms into the outer layer and the second material forms into the supporter. The second material includes a plurality of reinforcing fibers.

The refrigeration system is configured to adjust a temperature inside a vehicle compartment of the transport vehicle, the refrigeration system including an evaporator disposed in the vehicle compartment and the evaporator including evaporator coils (120) through which a refrigerant flows and a housing (110) for accommodating the evaporator coils; wherein the housing is further provided with a heating element (130); and the refrigeration system further includes a control module (140) configured to control the heating element. According to the refrigeration system for a transport vehicle, the control method thereof and the transport vehicle of the present disclosure, by disposing the heating element inside the housing of the evaporator, which is controlled to perform heating and stop heating according to actual situations, ice is prevented from being formed on the inner side of the housing, and condensation water is prevented from being formed on the outer side of the housing, thereby effectively improving the reliability of the preservation of goods.

The refrigeration system is configured to adjust a temperature inside a vehicle compartment of the transport vehicle, the refrigeration system including an evaporator disposed in the vehicle compartment and the evaporator including evaporator coils (120) through which a refrigerant flows and a housing (110) for accommodating the evaporator coils; wherein the housing is further provided with a heating element (130); and the refrigeration system further includes a control module (140) configured to control the heating element. According to the refrigeration system for a transport vehicle, the control method thereof and the transport vehicle of the present disclosure, by disposing the heating element inside the housing of the evaporator, which is controlled to perform heating and stop heating according to actual situations, ice is prevented from being formed on the inner side of the housing, and condensation water is prevented from being formed on the outer side of the housing, thereby effectively improving the reliability of the preservation of goods.