A fuel management method for long term stationary truck use is provided. This method includes a truck with at least a first saddle tank or a second saddle tank integral to the truck. Each saddle tank has a fuel level sensor to measure the fuel level. A fuel trailer provides supplemental fuel, and a fuel pump downstream of the fuel trailer and upstream of the truck pressurizes the fuel from the fuel trailer. The method includes supplying fuel to local users from saddle tanks, activating the fuel pump when the fuel level of both the saddle tanks is less than a first predetermined threshold, thereby transferring fuel from the fuel trailer to the first saddle tank and the second saddle tank, deactivating the fuel pump when the fuel level of either the saddle tanks is greater than a second predetermined threshold.

Apparatus (2) for monitoring a set of fuel dispensers (10.sub.1, 10.sub.2, . . . 10.sub.N) of filing stations (1.sub.1, 1.sub.2, . . . 1.sub.M), for providing fuel stored in tanks (11) to vehicles, may include interfaces (21) to receive measurements from output probes (30.sub.1, 30.sub.2, . . . 30.sub.N) measuring fuel flowing through nozzles (11.sub.1, 11.sub.2, . . . 10.sub.N); measurements from amount probes (31) measuring a stored amount contained within the tank; and receipt data of fuel delivered; a memory (22) to store at least part of said measurements, and a computing means (23). The computing means may be configured for: determining two subsequent fuel deliveries for which stored amounts measured at the start of said deliveries are substantially equals; determining a suspicious situation by comparing said receipt data corresponding to said subsequent fuel deliveries with the sum of measurements provided by said output probes during the time period between these two subsequent deliveries; and triggering an action when a suspicious situation is determined.

In general, intelligent fuel dispensers are provided. In at least some implementations, an intelligent fuel dispenser can determine customer identities and/or other characteristics and provide customized fueling sessions based on the determined customer identities and/or other characteristics. In at least some implementations, the fuel dispenser includes a touchless interface allowing customers to complete fueling sessions with minimal physical contact with the fuel dispenser.

A system for controlling selection and distribution of a product in a product dispensing system. The system includes a user interface for prompting a selection and selecting the product, a machine control processor in communication with the user interface, a power distribution module connected to the machine control processor, and a power supply unit for supplying power to the system through the power distribution module.

A fuel dispenser includes a power distribution system having an alternating current (AC) power supply and an AC to direct current (DC) power converter configured to convert a portion of the AC power to DC power for one or more DC peripheral components associated with the fuel dispenser. The power distribution system also includes processing circuitry configured to power down at least one of the DC peripheral components in response to an actuator, cause an indicator to be activated indicating that the DC peripheral components are de-energized and the AC power supply is active, power up the at least one direct current peripheral component in response to the actuator when the direct current peripherals are de-energized, and cause the indicator to be activated to indicate that both the DC peripheral components and the AC power supply are active.

A fuel dispenser includes a power distribution system having an alternating current (AC) power supply and an AC to direct current (DC) power converter configured to convert a portion of the AC power to DC power for one or more DC peripheral components associated with the fuel dispenser. The power distribution system also includes processing circuitry configured to power down at least one of the DC peripheral components in response to an actuator, cause an indicator to be activated indicating that the DC peripheral components are de-energized and the AC power supply is active, power up the at least one direct current peripheral component in response to the actuator when the direct current peripherals are de-energized, and cause the indicator to be activated to indicate that both the DC peripheral components and the AC power supply are active.

The Windshield Mojo is the only product of its kind that enables users to choose the amount of fluid to be dispensed into the vehicle's windshield reservoir and therefore guarantees a smoother, quicker, and more cost-effective operation. The Windshield Mojo is uniquely designed with a digital screen to enhance functionality and a coin and a card insert for easy payment and quick utilization.

A fuel storage and supply arrangement serves as a source of fuel to be dispensed via at least one fuel dispenser in a fuel dispensing environment. The arrangement comprises a storage tank for containing a quantity of the fuel. A pump assembly draws the fuel from the storage tank providing the fuel under pressure to a fuel supply line. A fuel conditioning assembly includes a housing having a storage volume, a housing inlet receiving the fuel under pressure created by the pump assembly, a housing outlet through which fuel exits the housing, and a housing port through which fuel can be drawn into the housing. A vacuum source in fluid communication with the housing outlet is operative to selectively apply a vacuum to the outlet of the housing so that liquid can be drawn into the housing via the port. A water intake device is in fluid communication with the housing port. The water intake device has at least one inlet situated adjacent to a bottom of the fuel storage tank.

The windshield washer fluid dispenser is a self-service station, that is capable of providing a user with high quality windshield washer fluid and the ability to utilize the windshield washer fluid manually. To accomplish this, the device includes a combination of components, that allows one to properly clean the windshield on one's vehicle without the need of an attendant. To accomplish this, the system includes a body, that houses a user-friendly dispenser container, a blend center unit that can instantaneously mix liquids to make a windshield washer solution, and a HID (human interface device) that can dispense the windshield washer solution according to users' needs. Further, the system includes a display device, a payment system, a sign board and necessary accessories that help with the smooth functioning of the system. Thus, the device utilizes simple, user-interactive, and cost-effective technologies to provide the windshield washer fluid dispenser self service station.

A system for monitoring flow conditions of fluid flowing from a product container through a solenoid pump. The system includes at least one solenoid pump comprising a solenoid coil, which, when energized, produces a stroke of the solenoid pump, at least one product container connected to the at least one solenoid pump wherein the at least one solenoid pump pumps fluid from the at least one product container during each stroke, at least one PWM controller configured to energize the at least one solenoid pump, at least one current sensor for sensing the current flow through the solenoid coil and producing an output of the sensed current flow, and a control logic subsystem for controlling the flow of fluids through the solenoid pump by commanding the PWM controller and for monitoring the current through the solenoid pump by receiving the output from the current sensor, wherein the control logic subsystem uses the measured current flow through the solenoid coil to determine whether the stroke of the solenoid pump is functional.