A strap system comprising a first strap extending between a first end and a second end. The first end is connected to a first attachment mechanism. The strap system further comprises a second strap extending between a third end and a fourth end. The fourth end is connected to a second attachment mechanism. The strap system comprises a load transmission device connected to the second end of the first strap and to the third end of the second strap. The load transmission device is arranged to transmit a signal in response to a tension force in the first and second straps falling below a threshold force.

A tension monitoring device that attaches or clamps onto to a tensioned cargo load securing strap and wirelessly communicates the tension level to the driver via a remote device, such as a mobile smartphone. One or more devices may be installed on a vehicle or trailer to be simultaneously monitoring the tension conditions during transit. The tension signal from the device is received and processed by the mobile smartphone application to display the real-time tension relative to unsafe levels and transmit alerts to the driver when an unsafe or undesired condition occurs. The tension monitoring device includes an electromechanical sensor and microprocessor, powered by a battery, and packaged inside two hinged weatherproof housings for the ability to clamp onto a tensioned cargo strap.

The technology relates to cargo vehicles. National, regional and/or local regulations set requirements for operating cargo vehicles, including how to distribute and secure cargo, and how often the cargo should be inspected during a trip. However, such regulations have been focused on traditional human-driven vehicles. Aspects of the technology address various issues involved with securement and inspection of cargo before a trip, as well as monitoring during the trip so that corrective action may be taken as warranted. For instance, imagery and other sensor information may be used to enable proper securement of cargo before starting a trip. Onboard sensors along the vehicle monitor the cargo and securement devices/systems during the trip to identify issues as they arise. Such information is used by the onboard autonomous driving system (or a human driver) to take corrective action depending on the nature of the issue.

A cargo restraint system a locking ring coupled to an extension tube, wherein the locking ring comprises an annular body and one or more tabs extending from the annular body. The cargo restrain system also includes a locking tube coupled to the main body. The locking tube comprises one or more grooves complementary to the shape and size of the tabs on the locking ring. The grooves of the locking tube inhibit rotational movement of the locking ring.

A device for measuring the tension in a tensioning belt comprises a retaining device for retaining a spring element, an elastically deformable spring element that is retained by the retaining device and on which a section of the tensioning belt can apply a force and elastically deform the spring element, the ends of the spring element being moved closer to one another when the tensioning force increases, and an electronic sensor unit. The sensor unit comprises a sensor system that measures the deflection of the spring element and generates a data signal, and a transmitter for transmitting the data signal to a receiving unit. The sensor system is situated at the ends of the spring element.

Methods and systems for receiving, by a destination device at which a securement-monitoring application is operating, from a securement sensor device, a securement-condition communication indicating a condition of a securement remote to the destination device. Operations also include determining, by the destination device using the securement-monitoring application, an action to take responsive to the securement-condition communication, such as notifying a user of an undesired condition at the securement. The operations further include initiating the action determined.

A cargo strap monitoring system for real-time detection and reporting of cargo strap failure is provided. The cargo strap monitoring system may be a detector in the form of a cylinder that fits a winch slot. The cylinder provides a housing for circuitry operably linked to a pressure sensor. During normal operation a cargo strap is wrapped around and deployed from the spindle. The pressure sensor detects unsafe tension in the cargo strap. The circuitry includes a transceiver and a processor. Upon detection of an unsafe tension condition the transceiver transmits a warning to a remote monitor which may be located in a driver's truck cab. The remote monitor can be a mobile terminal such as a smart phone. The spindle with a slot and circuitry including the pressure sensor can be sold as a kit suitable for retrofitting to cargo strap winches.

A cargo securing apparatus and a method of maintaining a user configured tension in a cargo securing element are disclosed. The apparatus includes at least one sensor arranged to measure a first and second tension in a tensile element (used to secure the cargo) at different times and a processor in data communication with the sensor. The processor is configured to receive the tension measurements from the sensor and to distinguish between acute and sustained deviations in tension based on the tension measurements. Conditionally, the processor may compare the first and second tension measurements to a user configured tension setting and determine tension correction parameters required to maintain the tension in the tensile element within a range of the user configured setting. The apparatus may include one or more manual or automated adjustment drives to adjust the tension in the tensile element in accordance with the tension correction parameters.

Vehicle which has a loading area, on which a load can be placed and by means of at least one load detector the presence of said load on said loading area can be detected, and by means of a central control unit the signals of all said load detectors can be detected and the measured value of the mass of said load can be detected, whereby said load can be secured by means of at least one movable, mechanical and flexible load securing device, which can be brought into contact with said load, and by means of at least one safety sensor the value of the force can be detected with which said load securing device acts on said load and for this force said central control unit calculates a reference value, depending on the mass of said load and according to a formula for the relevant applicable regulations and thereupon checks, if the actual value is sufficient.

In one embodiment, a cable reel restraint device comprises a cable reel, a retractable cable, first and second springs, first and second attachment interfaces, and a preload selection control. The retractable cable is configured to extend from and retract onto the cable reel. The first spring is configured to exert force for preloading the second spring, and the second spring is configured to exert force for retracting the retractable cable. The first attachment interface is coupled to the cable reel by a first spherical bearing, and the second attachment interface is coupled to the retractable cable by a second spherical bearing. Moreover, the first and second attachment interfaces are configured for being fastened to first and second attachment points. The preload selection control is configured to select a particular preload magnitude and cause the first spring to preload the second spring with a load of the particular preload magnitude.