Abstract: A self-correcting current transformer 100 combines a current transformer 113 and self-calibration electronics 115 into one device. The current transformer has a sensor coil 106 with a number of turns that is less than a target number of turns, to cause a secondary current 205 induced in the sensor coil to be greater than a target secondary current 404 corresponding to the target number of turns. A measurement circuit 116 integrated with the transformer, determines an error signal 214 representing how much greater the secondary current is than the target secondary current and outputs the error signal. A current sink circuit 129 integrated with the transformer, shunts an amount of current 216 from the sensor coil, based on the error signal, to reduce a magnitude of the secondary current to match the target secondary current. The measurement circuit and the current sink circuit may be powered by the secondary current.

Abstract: A distributed energy management method and system 100 are disclosed for managing a charge rate of an array of EVSEs 140 that share a common power source. In the disclosed method and system, control of the power sharing is distributed at the individual EVSE level. For example, each EVSE includes a communication device 540 and a controller 530. The communication device is used to receive a signal relating to a present current capacity utilization of the shared circuit, such as an indication of availability or unavailability of current capacity on the shared circuit. The controller is configured to generate a variable update interval, and initiate adjustment of the charge rate of the EVSE according to the variable update interval based on the present current capacity utilization as indicated by the received signal.

Abstract: The invention provides consistent settings between local and remote parameter adjustments of both local and remote HMI. A dial (4) is superimposed on a bistable display substrate (2), having an indicator (7) configured to be manually aligned with a displayed character representing a manual setting of a parameter value for controlling local equipment. A network interface (18) is connected over a communications network (17) to a remote HMI (16), configured to receive a new parameter value for controlling the local equipment (25). A controller (14) samples the current position of the indicator (7) of the dial (4), and provides a control input signal (20) to the bistable display substrate (2) to control a display of the new parameter value in the current position of the indicator (7) of the dial (4) and to provide the new parameter value to the local equipment (25).

Abstract: Systems, methods, devices, and computer-readable media detect a status of a cable 204, and in particular, a cable of electric supply equipment. An example of electric supply equipment is electric vehicle supply equipment 200, which may be used for charging an electric vehicle 201. The electric vehicle supply equipment 200 may include a cable 204 for delivering electric power from a power source to the electric vehicle 201. Further, the electric vehicle supply equipment 200 may include a cable detection subcircuit 225 for detecting a status of its cable 204. Specifically, the cable detection subcircuit 225 may detect whether the cable 204 has been removed. Further, the electric vehicle supply equipment 200 may take various actions based on results provided by the cable detection subcircuit 225.

Abstract: An electric vehicle supply equipment includes EVSE control electronics, an EV connector and an HMI circuit, the HMI circuit including a proximity input terminal configured to receive a proximity signal from an EV connector indicating a state of a handle button of the EV connector, a ground terminal, a current source input coupled between the proximity input terminal and the ground terminal, a comparator connected between the proximity input terminal and the ground terminal to provide an output representing a state of the handle button when the current source is activated by the control input and an output terminal to which the output of the comparator is connected, the output terminal being connected to the EVSE control electronics, wherein the state of the handle button is utilized as an input to the HMI circuit.

Abstract: A temperature sensor 120 automatically shuts down charging operations in response to a temperature increase in a charging handle 150 of an electric vehicle charging station 100. The temperature sensor is connected between a ground conductor and a high voltage conductor L1 in the charging handle. The charging handle includes a return conductor L2/N. The temperature sensor includes a thermistor R1-NTC that changes its resistance in response to an increase in temperature in the charging handle. A portion of current in the high voltage conductor is diverted to the ground conductor, instead of the return conductor, in response to the thermistor sensing a temperature increase, thereby causing a ground fault detector 160 to trip in the charging station.

Abstract: An add-on adapter 110 enables a single charging port 102 of an electric vehicle charging station 100 to simultaneously charge two electric vehicles. An adapter controller 120 determines the available charging rate offered by the charging station. Electric vehicle charging handles 150A, 150B are determined to be connected to the electric vehicles. A charge sharing control circuit 300 in the adapter controller, determines modified available charging rates to be offered for simultaneously charging the electric vehicles. The modified available charging rates are based on the connection states of the electric vehicles and the available charging rate offered by the charging station. The adapter controller controls two contactors 130A, 130B to switchably connect a charging station power socket to the electric vehicle charging handles, to provide shared power at the determined modified available charging rate to the electric vehicles, for simultaneous charging.

Abstract: A circuit measures temperature in a charging handle 150 of an electric vehicle charging station (EVSE) 100. A temperature sensor is connected between a control pilot line 115 and ground line G in the charging handle of the EVSE. The control pilot line transmits a square wave signal CP having positive and negative portions, to an electric vehicle, according to the SAE J1772 standard. A temperature monitor 300 in the EVSE, coupled to a pilot signal measurement circuit 230 in the EVSE, measures the negative portions of the square wave signal resulting from the temperature sensor conducting current in response to changes in temperature in the handle. Temperature measurement of the charging handle is achieved without significant added cost or complexity, by reusing existing components in the EVSE, with little or no modification required to EVSE electronics, and minimal modification of the handle.

Abstract: A synthetic fault signal generator assembly is remotely located on a branch circuit downstream from a circuit breaker protecting a load. The synthetic fault signal generator assembly is configured to detect an improper circuit condition that is not independently detected, detectable, or actionable by the circuit breaker such as, for example, a load or outlet receptacle specific problem that can lead to equipment damage or property damage if not mitigated. In response to the improper circuit condition being detected, the synthetic fault signal generator assembly generates a synthetic fault signal, which causes the circuit breaker to trip. The synthetic fault signal generator assembly can inject the synthetic fault signal into the branch circuit to provide the synthetic fault signal to the circuit breaker.

Abstract: A method detects a shorted charging cable of an electric vehicle charging station. A charging cable of the electric vehicle charging station is determined to not be connected to an electric vehicle. An impedance test may then be performed between conductors of the charging cable while not connected to an electric vehicle. A contactor between a source of electrical power and the conductors is prevented from closing, in response to detecting a short between the conductors, and a warning signal is output. The impedance test is disabled in response to receiving a signal indicating that the charging cable has become connected to an electric vehicle, so as to not interfere with normal charging. In this manner, by detecting a short circuit in the charging cable before the contactors are closed, the contactor's contacts are prevented from becoming welded closed by a short circuit in the charging cable.

Abstract: A cable reel assembly in an electric vehicle supply equipment (EVSE) having a reel around which a cable is coiled. A shaft supporting the reel bears discs that rotate with the reel, and calipers coupled to the discs stop them and the reel from rotating. The power L1 and L2 conductors in the cable are electrically connected to the discs, and the calipers are electrically connected to the power source for the EVSE so that the calipers provide mechanical and electrical connection when actuated. Optionally, slip rings coupled to the shaft are connected to the control pilot and proximity signal conductors in the cable. Thus, during cable re traction, the control pilot and proximity signals are still provided to the EVSE, but the power conductors are decoupled from the power source. Only when the calipers are actuated to brake the discs is current flow permitted.

Abstract: A self-correcting current transformer 100 combines a current transformer 113 and self-calibration electronics 115 into one device. The current transformer has a sensor coil 106 with a number of turns that is less than a target number of turns, to cause a secondary current 205 induced in the sensor coil to be greater than a target secondary current 404 corresponding to the target number of turns. A measurement circuit 116 integrated with the transformer, determines an error signal 214 representing how much greater the secondary current is than the target secondary current and outputs the error signal. A current sink circuit 129 integrated with the transformer, shunts an amount of current 216 from the sensor coil, based on the error signal, to reduce a magnitude of the secondary current to match the target secondary current. The measurement circuit and the current sink circuit may be powered by the secondary current.

Abstract: Systems, methods, apparatuses, and computer-readable media provide electric supply equipment 200 configured to perform diagnostics. The electric supply equipment 200 may include a receptacle 210 for forming a closed circuit loop. The electric supply equipment 200 includes a connector 203 for charging devices, such as electric vehicles 101. The connector 203 may include one or more conductors, some of which may be wrapped with insulation. When the connector 103, 203 is not used for charging, the connector 203 may be connected to a receptacle 210 of the electric supply equipment 200. Thus, the electric supply equipment 200, via the receptacle 210, may form a closed loop circuit with the conductors. Further, the electric supply equipment 200 may include a diagnostic unit 250 for performing diagnostic tests on the conductors. In particular, the diagnostic unit 250 may access ends of the conductors via the receptacle 210.

Abstract: A method and apparatus for composing a desirable trip curve, such as an I2*t trip curve, for an electrical protective device from at least one less desirable trip curve, such as an I*t trip curve. The method is accomplished by defining a selected parameter of the desirable overload trip curve and defining the selected parameter as a function of one or more monitored input values, such as current, trip class or phase unbalance, and modulating the selected defined parameter value between a maximum boundary trip curve and a minimum boundary trip curve. The modulated parameter is used to adjust the less desirable trip curve such that it has the characteristics of the desired trip curve. The method is implemented by one or more electrical circuits (filter circuits) representing the less desirable trip curve(s) and composing an output signal representing the desirable trip curve by modulating between the one or more electrical circuits.

Abstract: Systems, methods, devices, and computer-readable media detect a status of a cable 204, and in particular, a cable of electric supply equipment. An example of electric supply equipment is electric vehicle supply equipment 200, which may be used for charging an electric vehicle 201. The electric vehicle supply equipment 200 may include a cable 204 for delivering electric power from a power source to the electric vehicle 201. Further, the electric vehicle supply equipment 200 may include a cable detection subcircuit 225 for detecting a status of its cable 204. Specifically, the cable detection subcircuit 225 may detect whether the cable 204 has been removed. Further, the electric vehicle supply equipment 200 may take various actions based on results provided by the cable detection subcircuit 225.

Abstract: Systems, methods, apparatuses, and computer-readable media provide electric supply equipment 200 configured to perform diagnostics. The electric supply equipment 200 may include a receptacle 210 for forming a closed circuit loop. The electric supply equipment 200 includes a connector 203 for charging devices, such as electric vehicles 101. The connector 203 may include one or more conductors, some of which may be wrapped with insulation. When the connector 103, 203 is not used for charging, the connector 203 may be connected to a receptacle 210 of the electric supply equipment 200. Thus, the electric supply equipment 200, via the receptacle 210, may form a closed loop circuit with the conductors. Further, the electric supply equipment 200 may include a diagnostic unit 250 for performing diagnostic tests on the conductors. In particular, the diagnostic unit 250 may access ends of the conductors via the receptacle 210.

Abstract: An Electric Vehicle is equipped to communicate its state of charge and other vehicular information to AC-charging Electric Vehicle Supply Equipment which can present and manage charging options based on the state of charge information and user selected options. An array of Electric Vehicle Supply Equipment may be managed utilizing the state of charge information from a plurality of Electric Vehicles connected to the array.

Abstract: A method and apparatus for composing a desirable trip curve, such as an I2*t trip curve, for an electrical protective device from at least one less desirable trip curve, such as an I*t trip curve. The method is accomplished by defining a selected parameter of the desirable overload trip curve and defining the selected parameter as a function of one or more monitored input values, such as current, trip class or phase unbalance, and modulating the selected defined parameter value between a maximum boundary trip curve and a minimum boundary trip curve. The modulated parameter is used to adjust the less desirable trip curve such that it has the characteristics of the desired trip curve. The method is implemented by one or more electrical circuits (filter circuits) representing the less desirable trip curve(s) and composing an output signal representing the desirable trip curve by modulating between the one or more electrical circuits.