Abstract: A resistance soldering system includes a power input receiving an alternating current from a power source and a controller circuit generating a control signal indicative of a desired power level delivered for a desired time. The resistance soldering system further includes a silicon-controlled rectifier connected to the power input and the controller circuit and producing a control voltage proportional to the control signal and a transformer having a primary side receiving the control voltage and a secondary side having output leads configured to apply an output voltage to a solder joint disposed between the output leads. The controller circuit determines the control signal applied to the silicon-controlled rectifier required to melt the solder joint based on the desired power level and the desired time. The controller circuit controls the desired power level independent of the desired time. A method of operating a resistance soldering system is also presented.

Abstract: A resistance soldering system includes a power input receiving an alternating current from a power source and a controller circuit generating a control signal indicative of a desired power level delivered for a desired time. The resistance soldering system further includes a silicon-controlled rectifier connected to the power input and the controller circuit and producing a control voltage proportional to the control signal and a transformer having a primary side receiving the control voltage and a secondary side having output leads configured to apply an output voltage to a solder joint disposed between the output leads. The controller circuit determines the control signal applied to the silicon-controlled rectifier required to melt the solder joint based on the desired power level and the desired time. The controller circuit controls the desired power level independent of the desired time. A method of operating a resistance soldering system is also presented.

Abstract: A power delivery system includes a power-input-channel, an AC/DC converter, one or more controller-circuits, a silicon-controlled-rectifier, a transformer, and a pair of output-leads. The power-input-channel receives alternating-current from a power-source. The AC/DC converter converts the alternating-current to a direct-current at a converter-output. The one or more controller-circuits are connected with the converter-output and control a signal indicative of a desired-power-level delivered for a desired-time. The silicon-controlled-rectifier is connected with the power-input-channel and controls an SCR-output-voltage to an SCR-output-channel proportional to the signal. The transformer reduces the SCR-output-voltage from a primary-side to a secondary-voltage on a secondary-side. The pair of output-leads are connected with poles of the secondary-side. A solder-joint is disposed between the pair of output-leads.

Abstract: A power delivery system includes a power-input-channel, an AC/DC converter, one or more controller-circuits, a silicon-controlled-rectifier, a transformer, and a pair of output-leads. The power-input-channel receives alternating-current from a power-source. The AC/DC converter converts the alternating-current to a direct-current at a converter-output. The one or more controller-circuits are connected with the converter-output and control a signal indicative of a desired-power-level delivered for a desired-time. The silicon-controlled-rectifier is connected with the power-input-channel and controls an SCR-output-voltage to an SCR-output-channel proportional to the signal. The transformer reduces the SCR-output-voltage from a primary-side to a secondary-voltage on a secondary-side. The pair of output-leads are connected with poles of the secondary-side. A solder-joint is disposed between the pair of output-leads.

Abstract: Disclosed is a coating composition comprising a resinous binder prepared from a reaction mixture comprising (a) a first component; (b) a second component; and (c) a third component comprising a block copolymer having (i) a first block comprising units having functional groups reactive with at least one of the first and second components and (ii) a second block comprising units having functional groups that promote adhesion to a polymeric substrate, provided that the first component, the second component, and the block copolymer differ from each other. The block copolymer may also be used as an additive in a coating composition.

Abstract: Disclosed is a coating composition comprising a resinous binder prepared from a reaction mixture comprising (a) a first component; (b) a second component; and (c) a third component comprising a block copolymer having (i) a first block comprising units having functional groups reactive with at least one of the first and second components and (ii) a second block comprising units having functional groups that promote adhesion to a polymeric substrate, provided that the first component, the second component, and the block copolymer differ from each other. The block copolymer may also be used as an additive in a coating composition.