A Local Controller device installed in or on the fuel pump capable of functioning as a pump controller dedicated solely to the pump in which it is installed and as a data router to and from the peripheral devices. This dedicated Local Controller o device contains a microcomputer with a pump communications interface and optionally a remote, Site Controller communication interface which is non-dedicated and has control over many pumps at the station. If connected to such a Site Controller, the device will function as a slave to this Site Controller. Otherwise it functions autonomously to control the pump on its own.

A Local Controller device installed in or on the fuel pump capable of functioning as a pump controller dedicated solely to the pump in which it is installed and as a data router to and from the peripheral devices. This dedicated Local Controller o device contains a microcomputer with a pump communications interface and optionally a remote, Site Controller communication interface which is non-dedicated and has control over many pumps at the station. If connected to such a Site Controller, the device will function as a slave to this Site Controller. Otherwise it functions autonomously to control the pump on its own.

Disclosed herein are devices, methods, and systems that useful for allowing consumers to purchase a fluid in limited and/or discrete amounts or volumes, for example as-needed, daily, weekly, etc. In various embodiments, the disclosed devices, systems, and methods provide for an innovative fluid distribution system, including a device that can receive and monitor payment for a discrete amount of fluid, measure the fluid as it flows through the device, and stop fluid flow when the discrete amount of fluid has flowed through the device. The disclosed device may be in communication with a central server for receiving payment from the user, and providing information to the central server of the device's status.

Systems and methods for financial settlement of transactions within an electric power grid network are disclosed. A multiplicity of active grid elements are constructed and configured for electric connection and network-based communication over a blockchain-based platform. The multiplicity of active grid elements are operable to make peer-to-peer transactions based on their participation within the electric power grid by generating and executing a digital contract. The multiplicity of active grid elements generate messages autonomously and/or automatically within a predetermined time interval. The messages comprise energy related data and settlement related data. The energy related data of the multiplicity of active grid elements are based on measurement and verification. The energy related data and the settlement related data are validated and recorded on a distributed ledger with a time stamp and a geodetic reference.

A Local Controller device installed in or on the fuel pump capable of functioning as a pump controller dedicated solely to the pump in which it is installed and as a data router to and from the peripheral devices. This dedicated Local Controller device contains a microcomputer with a pump communications interface and optionally a remote, Site Controller communication interface which is non-dedicated and has control over many pumps at the station. If connected to such a Site Controller, the device will function as a slave to this Site Controller. Otherwise it functions autonomously to control the pump on its own.

A Local Controller device installed in or on the fuel pump capable of functioning as a pump controller dedicated solely to the pump in which it is installed and as a data router to and from the peripheral devices. This dedicated Local Controller device contains a microcomputer with a pump communications interface and optionally a remote, Site Controller communication interface which is non-dedicated and has control over many pumps at the station. If connected to such a Site Controller, the device will function as a slave to this Site Controller. Otherwise it functions autonomously to control the pump on its own.

Methods, systems, and devices for secure payment and providing multimedia at fuel dispensers are provided. In general, a fuel dispenser can include a terminal configured to receive secure information and to show multimedia. The terminal can be configured to switch between a first mode and a second mode. The terminal can include a touchscreen. In the first mode, the touchscreen can have a shield enabled thereon that is configured to reduce a field of view of the touchscreen such that the touchscreen is only visible from specific angle(s). In the second mode, the shield can be disabled such that the touchscreen does not have a reduced field of view.

Methods and systems for sharing digital electronic keys (e-keys) to use a vehicle with the e-key are provided. One example method includes sending, via a first application of a first mobile device, a message to a second mobile device to initiate providing access to the vehicle via the e-key. The method includes receiving, by the first mobile device, data confirming from the second mobile device indicating receipt and creating the e-key at the second mobile device for the vehicle with a level of access that was set via the first application of the first mobile device. The data confirming receipt for the e-key is authenticated by the first mobile device. The method includes sending, by the first mobile device, verification of the e-key for use via the second mobile device. The e-key is registered with a server to enable activation of the e-key on the second mobile device. A second application of the second mobile device provides a user interface for access of the e-key for unlocking and starting the vehicle. In one example, the e-key is usable via wireless communication with the vehicle over a near field communication (NFC) connection. In one example, the first application of the first mobile device is provided with an interface to enable revocation to disable the e-key shared with a user of the second mobile device.

A charging locker includes a charging locker frame defining a locker stack compartment and an adjacent wiring and access compartment. A plurality of lockers are located within the locker stack compartment. A plurality of locker doors are provided which correspond to the plurality of lockers, and selectively individually provide access to interiors of respective lockers from a front of the charging locker. The charging locker also includes a wiring and access compartment door selectively providing access to an interior of the wiring and access compartment from the front of the charging locker. The wiring and access compartment is configured to extend in a vertical direction and is horizontally adjacent to each of the lockers located within the locker stack compartment.

A pre-staged or in-person provided order is received from a customer location. Order details are sent to a fulfillment terminal and items associated with the order are prepared or collected. The items are loaded into an autonomous device. The autonomous device plans a route from its current location to the customer location and the autonomous device navigates from its current location to the customer location using the route. The customer is verified at the autonomous device and a secure bin is unlocked by the autonomous device. The customer removes the items associated with the order from the unlocked secure bin, and the autonomous device navigates back to its original location within an enterprise.