A use management device includes: a traveling information acquisition part which acquires subsequent prospective traveling information about an electrically driven cart; a remaining amount information acquisition part which acquires remaining amount information about a battery; a determination section which determines, based on the prospective traveling information and the remaining amount information, whether charging of the battery is necessary; and a control section which executes a permission control of permitting a traveling motor to drive when the determination section determines that the charging of the battery is unnecessary, and executes a forbidding control of forbidding the traveling motor from driving when the determination section determines that the charging of the battery is necessary.

Various implementations include approaches for training a surface detection classifier and detecting characteristics of a surface, along with related micromobility vehicles. Certain implementations include a method including: comparing: i) detected movement of a micromobility (MM) vehicle or a device located with a user at the MM vehicle while operating the MM vehicle, with ii) a surface detection classifier for the MM vehicle; and in response to detecting that the MM vehicle is traveling on a restricted surface type for a threshold period, performing at least one of: a) notifying an operator of the MM vehicle about the travel on the restricted surface type, b) outputting a warning at an interface connected with the MM vehicle or the device, c) limiting a speed of the MM vehicle, or d) disabling operation of the MM vehicle.

An ECU performs a process including: when a vehicle establishes a Ready-On state, selecting a CD mode; when discharging power is uncompleted and a scheduled time to return the vehicle is a time within a discharging period, setting a second target SOC as a mode switching value; and when the vehicle's power storage device has an SOC reaching the mode switching value and a surcharge imposed on a rental fee is unaccepted, switching the current control mode from the CD mode to a CS mode.

A system and method for actuating battery power for a mower that include receiving an input through a battery status switch of the battery. The system and method also include inputting a battery actuation switch based on receiving the input through the battery status switch. The system and method additionally include supplying an electronic signal to a microprocessor of the battery to supply power to a motor controller of the mower based on the input of the battery actuation switch. The system and method further include supplying electrical voltage to a motor of the mower to operate the motor based on the power supplied to the motor controller from the battery.

There are described herein methods and systems for operating an electric motor of a watercraft. In one method, the electric motor of the watercraft is controlled based on commands received from an accelerator of the watercraft, a sensor signal is received from at least one sensor of the watercraft while the electric motor is in operation, the sensor signal indicative of an undesirable condition of a water intake of the watercraft, and a change is effected to the controlling of the electric motor in response to receiving the sensor signal.

An apparatus including a first electrical connector; and a second electrical connector. The first and second electrical connectors have magnets to provide a magnetic holding force with each other and provide alignment of the electrical connectors to hold the second electrical connector against the first electrical connector at a predetermined position. Magnetic poles of the magnets are configured to limit orientation of the second electrical connector on the first electrical connector. The second electrical connector includes two power contacts and an interruption detector contact, where the power contacts are movably mounted on the second housing and configured to disconnect from electrical contacts of the first electrical connector, when the second electrical connector is being disconnected from the first electrical connector, only after the interruption detector contact of the second plurality of electrical contacts disconnects from an electrical contact of the first electrical connector.

A server includes a charge schedule creation unit that creates a charge schedule for external charging of a vehicle. When user-specified-time information for determining a time to perform the external charging is not given by a user of the vehicle, the charge schedule creation unit creates a first charge schedule. When the user-specified-time information is given, the charge schedule creation unit creates a second charge schedule. In the first charge schedule, a battery mounted in the vehicle is pre-charged with some of power to be charged to the battery, and, after the pre-charging is performed, the battery is charged with a remaining amount of the power during a time period in which an electricity cost is inexpensive. In the second charge schedule, the battery is charged, without the pre-charging being performed.

A mobile work system and methods for operationally receiving a work performing and/or energy delivering attachment. A work platform is powered by a power output device and includes a source of electricity for powering the attachment. The platform has a first end and a second end generally opposite the first end. A first attachment interface is connected to the first end, and a second attachment interface, substantially operationally equivalent to the first attachment interface, is connected to the second end. The first end of the platform also includes a first steering mechanism, and the second end includes a second steering mechanism substantially operationally equivalent to the first steering mechanism, whereby the platform is configured to be propelled and steered in a first direction and propelled and steered in a second direction generally opposite the first direction by the first and second steering mechanisms, respectively.

Vehicles can employ onboard telematic monitoring devices to collect vehicle and operation data, such as for improved vehicle fleet management. Such telematic monitoring devices are dependent on power from a vehicle, such that data collection and communication can be interrupted if a telematic monitoring device is disconnected or has a poor connection. The present disclosure relates to battery devices, which provide power to telematic monitoring devices as needed in order to maintain data collection and communication, or other more limited functionality. The present disclosure also relates to systems including battery devices, and methods for operating battery devices. The present disclosure also relates to detecting temperature of batteries, as well as emergency input and messages for telematic monitoring systems.

A vehicle system is directed to providing a driver with a utility mode, which is an indoor environment condition of a vehicle where it may be rested, and includes: a vehicle communication portion that is configured to receive a first request message requesting execution of the utility mode by communicating with a service terminal provided in the vehicle or a driver terminal possessed by the driver; and a vehicle controller that is configured to set electric components and controllers involved in driving of the vehicle to an off mode when an entry condition for the execution of the utility mode is satisfied and the vehicle's starting is in an on-state, and sets an air conditioning device controlling an indoor air condition of the vehicle and a stack generating power required in the utility mode to a driving mode to execute the utility mode.