Abstract: In an embodiment, during an overload or short circuit condition, a current limit circuit of an inverter is utilized in a pulse-by-pulse manner, which in turn causes the AC output of the inverter to operate in a hiccup mode (e.g., pulse-by-pulse based on and off dependent upon the output current) and automatically recover once the operating parameters (e.g., output current) are within the proper ranges. The pulse-by-pulse current limit circuit is configured to protect the switching circuits of the inverter from shorting or device failure during any peak operating voltage conditions by ensuring on/off timing accuracy of the inverter.

Abstract: In an embodiment, during an overload or short circuit condition, a current limit circuit of an inverter is utilized in a pulse-by-pulse manner, which in turn causes the AC output of the inverter to operate in a hiccup mode (e.g., pulse-by-pulse based on and off dependent upon the output current) and automatically recover once the operating parameters (e.g., output current) are within the proper ranges. The pulse-by-pulse current limit circuit is configured to protect the switching circuits of the inverter from shorting or device failure during any peak operating voltage conditions by ensuring on/off timing accuracy of the inverter.

Abstract: In an embodiment, during an overload or short circuit condition, a current limit circuit of an inverter is utilized in a pulse-by-pulse manner, which in turn causes the AC output of the inverter to operate in a hiccup mode (e.g., pulse-by-pulse based on and off dependent upon the output current) and automatically recover once the operating parameters (e.g., output current) are within the proper ranges. The pulse-by-pulse current limit circuit is configured to protect the switching circuits of the inverter from shorting or device failure during any peak operating voltage conditions by ensuring on/off timing accuracy of the inverter.

Abstract: A voltage transient protection utilizes Zener diodes, resisters, and a power MOSFET to clamp down the DC spike or surged voltage at the input and prevent damage to the inverter's DC power and control section. The input reverse polarity protection utilizes blocking diodes and a switch to cut off reverse voltage and prevent damage to the DC power and control section of the inverter. Once the surge voltage and/or reverse voltage conditions have been removed, the inverter will automatically recover and power on. In addition, an AC output interlock protection circuit is in place to provide safety protection to the external load. The AC output interlock protection circuit utilizes interlock jumpers on the mating connectors, which when detected (or in response to a control signal), it will activate the internal power relays and enable the AC output voltage to the terminals coupled to the external load.

Abstract: A method and system for rapidly preparing lithium carbonate or concentrated brine using high-temperature steam. The method comprises the steps of: feeding brine into a reactor, heating the brine with high-temperature steam above 200° C. while simultaneously discharging steam produced in the reactor, cooling and condensing the discharged steam in a condenser and collecting the condensate, and stopping the high-temperature steam after the brine is concentrated to a predetermined concentration or after a sufficient amount of lithium carbonate is collected. The system comprises: a reactor provided with a brine inlet, a steam outlet connected to a condenser, a product outlet, and a plurality of steam pipes. The method concerns the direct heating of brine using high-temperature steam, which is effective and efficient, and also produces fresh water. The heating is uniform and rapid, and does not require jackets, heat exchange tubes, mixers and vacuum pumps, vastly simplifying the system.

Abstract: A method for accelerating evaporation of brine in plateau salt lakes includes introducing downward wind to a brine surface; and changing the downward wind to transversal wind horizontally flowing outward when the wind contacts with the brine surface, to accelerate evaporation of the brine. Said method is simple in operation, can accelerate the evaporation of the brine, and can realize industrialized brine production at low cost. It is less prone to form salt deposits in concentrated brine, and is also easy to separate salt crystals precipitated from brine. Said device has a simple and reliable structure; low costs for the manufacture, use, and maintenance thereof; and improved evaporation of brine. Said device is convenient to be used in plateau salt-lake regions and easy to be relocated and with a minimal contact area with brine, it is essentially impossible to form salts deposits on the surface of the device.

Abstract: A method and system for rapidly preparing lithium carbonate or concentrated brine using high-temperature steam. The method comprises the steps of: feeding brine into a reactor, heating the brine with high-temperature steam above 200° C. while simultaneously discharging steam produced in the reactor, cooling and condensing the discharged steam in a condenser and collecting the condensate, and stopping the high-temperature steam after the brine is concentrated to a predetermined concentration or after a sufficient amount of lithium carbonate is collected. The system comprises: a reactor provided with a brine inlet, a steam outlet connected to a condenser, a product outlet, and a plurality of steam pipes. The method concerns the direct heating of brine using high-temperature steam, which is effective and efficient, and also produces fresh water. The heating is uniform and rapid, and does not require jackets, heat exchange tubes, mixers and vacuum pumps, vastly simplifying the system.

Abstract: An electrical connector includes an insulative housing, a plurality of terminals and a pair of board locks retained in the housing. The insulative housing defines a mating surface, a mounting surface opposite to the mating surface, a plurality of passageways penetrating through the mating surface and a pair of slots penetrating through the mounting face and a first side face of the insulative housing. The terminals are received in the passageways. The board locks are secured in the corresponding slots of the insulative housing. Each board lock includes a retention portion and a lock tail extending from the retention portion beyond the mounting face. The insulative housing further defines a pair of block portions unitarily protruding from the first side face adjacent to the corresponding slots, and each board lock includes a retaining portion abutting against the corresponding block portion on a face opposite to the mounting face.

Abstract: An electrical connector includes an insulative housing, a plurality of terminals and a pair of board locks retained in the housing. The insulative housing defines a mating surface, a mounting surface opposite to the mating surface, a plurality of passageways penetrating through the mating surface and a pair of slots penetrating through the mounting face and a first side face of the insulative housing. The terminals are received in the passageways. The board locks are secured in the corresponding slots of the insulative housing. Each board lock includes a retention portion and a lock tail extending from the retention portion beyond the mounting face. The insulative housing further defines a pair of block portions unitarily protruding from the first side face adjacent to the corresponding slots, and each board lock includes a retaining portion abutting against the corresponding block portion on a face opposite to the mounting face.

Abstract: Techniques for sequencing switched single capacitor for automatic equalization of batteries connected in series are described herein. In one embodiment, a battery equalizer includes a single capacitor, at least two switching circuits to be coupled to each of at least two batteries coupled in series. The battery equalizer further includes at least two driver circuits corresponding the at least two switching circuits and a controller. The controller is programmed to control the driver circuits in order to drive the switching circuits to sequentially couple the single capacitor to one of the batteries coupled in series during charging and/or discharging of the batteries. Only one of the switching circuits is turned on at a given time such that only one of the batteries is coupled to the single capacitor at the given time. Other methods and apparatuses are also described.

Abstract: Techniques for high performance inverter charger systems are described herein. In one embodiment, a power supply system includes, but is not limited to, an inverter to generate an AC (alternating current) output based on a DC (direct current) input, a current sensing circuit coupled to the inverter to sense an amount of current drawn from the inverter, and a microcontroller coupled to the inverter and the current sensing circuit to reduce the AC output of the inverter according to a predetermined algorithm stored within the microcontroller, in response to a detection that the amount of current drops below a predetermined threshold. Other methods and apparatuses are also described.

Abstract: Techniques for sequencing switched single capacitor for automatic equalization of batteries connected in series are described herein. In one embodiment, a battery equalizer includes a single capacitor, at least two switching circuits to be coupled to each of at least two batteries coupled in series. The battery equalizer further includes at least two driver circuits corresponding the at least two switching circuits and a controller. The controller is programmed to control the driver circuits in order to drive the switching circuits to sequentially couple the single capacitor to one of the batteries coupled in series during charging and/or discharging of the batteries. Only one of the switching circuits is turned on at a given time such that only one of the batteries is coupled to the single capacitor at the given time. Other methods and apparatuses are also described.

Abstract: Techniques for high performance inverter charger systems are described herein. In one embodiment, a power supply system includes, but is not limited to, an inverter to generate an AC (alternating current) output based on a DC (direct current) input, a current sensing circuit coupled to the inverter to sense an amount of current drawn from the inverter, and a microcontroller coupled to the inverter and the current sensing circuit to reduce the AC output of the inverter according to a predetermined algorithm stored within the microcontroller, in response to a detection that the amount of current drops below a predetermined threshold. Other methods and apparatuses are also described.