Abstract: A shower lamp assembly is formed with a water driven electric generator to power an LED light source. The assembly includes a first channel directing water to drive the generator. The generator is supported on a movable portion of a bypass valve that opens on a high water flow condition to direct a portion of the water to a second channel way from the generator. The generator is otherwise tuned to provide sufficient electricity under low water flow conditions to properly power the lamp. The lamp generator is then protected by the bypass valve from damage during high water flow conditions.

Abstract: A shower lamp assembly is formed with a water driven electric generator to power an LED light source. The assembly includes a first channel directing water to drive the generator. The generator is supported on a movable portion of a bypass valve that opens on a high water flow condition to direct a portion of the water to a second channel way from the generator. The generator is otherwise tuned to provide sufficient electricity under low water flow conditions to properly power the lamp. The lamp generator is then protected by the bypass valve from damage during high water flow conditions.

Abstract: A dual-acting solenoid, consisting of one armature moving between two latching positions against two yokes with two drive windings, is interconnected to bring out three wire terminations: a center and two ends. The electronic drive circuitry is similarly configured for three terminals. Optionally, the drive circuitry includes sensing and computation sufficient to determine the two currents and the two inductive voltages associated with the two windings. A method is shown for using six measured or computed parameters, two inductive voltages, two currents, and two time derivatives of current, to determine the simultaneous position and velocity of the armature. The method involves simultaneous solution of the equations for current and voltage in two time-varying inductors where the two inductances are constrained to correspond to the position of a single armature moving between two fixed magnetic yokes.

Abstract: A system combines reverse electrodialysis and electrolysis to produce hydrogen gas from the controlled mixing of fresh and salt water. A battery stack is formed of alternating membranes of selectively cation-permeable and anion-permeable membranes. Alternating solutions of fresh and salt water flow between the alternating membrane types, causing cations to flow in one direction and anions in the opposite direction, generating a current and cumulative voltage through the stack—this is reverse electrodialysis. The ends of the stack are terminated in electrodes which are shorted together. A recirculating reagent solution flows back and forth between the cells adjacent to the end electrodes, promoting a hydrogen-producing electrolysis and avoiding generation of unwanted chemicals, for example, chlorine. Alterations in the reagent can cause production of antimicrobial compounds for cleansing the membranes. Periodic polarity reversals reduce membrane scale buildup and enhance efficiency.

Abstract: Servo control using ferromagnetic core material and electrical windings is based on monitoring of winding currents and voltages and inference of magnetic flux, a force indication; and magnetic gap, a position indication. Third order nonlinear servo control is split into nested control loops: a fast nonlinear first-order inner loop causing flux to track a target by varying a voltage output; and a slower almost linear second-order outer loop causing magnetic gap to track a target by controlling the flux target of the inner loop. The inner loop uses efficient switching regulation, preferably based on controlled feedback instabilities, to control voltage output. The outer loop achieves damping and accurate convergence using proportional, time-integral, and time-derivative gain terms. The time-integral feedback may be based on measured and target solenoid drive currents, adjusting the magnetic gap for force balance at the target current.

Abstract: The invention provides a method of forming a patterned phosphor structure having red, green and blue sub-pixel elements for an AC electroluminescent display. The method involves selecting first and second phosphors, each emitting light in different ranges of the visible spectrum, but whose combined emission spectra contains red, green and blue light; depositing and patterning the phosphors in a layer to form a plurality of repeating phosphor deposits; and providing means associated with the phosphor deposits, and which together with the phosphor deposits form the red, green and blue sub-pixel phosphor elements, for setting and equalizing the threshold voltages, and for setting the relative luminosities of the red, green and blue sub-pixel phosphor elements so that they bear set ratios to one another at each modulation voltage used to generate the desired luminosities for red, green and blue; and optionally annealing the patterned phosphor structure so formed.

Abstract: A patterned phosphor structure and EL laminate containing same, forming red, green and blue sub-pixel phosphor elements for an AC electroluminescent display. The patterned phosphor structure includes at least a first and a second phosphor emitting light in different ranges of the visible spectrum, but with combined emission spectra contains red, green and blue light, the first and second phosphors being in a layer, arranged in adjacent, repeating relationship to each other to provide a plurality of repeating first and second phosphor deposits.

Abstract: A patterned phosphor structure, and EL laminate containing same, forming red, green and blue sub-pixel phosphor elements for an AC electroluminescent display. The patterned phosphor structure includes at least a first and a second phosphor emitting light in different ranges of the visible spectrum, but with combined emission spectra contains red, green and blue light, the first and second phosphors being in a layer, arranged in adjacent, repeating relationship to each other to provide a plurality of repeating first and second phosphor deposits.