A thermal overload device containing a polymer composite, which contains at least one polymer and a modified graphite oxide material, containing thermally exfoliated graphite oxide having a surface area of from about 300 m.sup.2/g to 2600 m.sup.2/g, and a method of making the same.

A unit can include a power supply interface; a processor board power interface operatively coupled to the power supply interface where the processor board power interface operatively couples to and supplies power to a processor board; a serial interface that operatively couples to the processor board; a microcontroller operatively coupled to the serial interface; memory operatively coupled to the microcontroller; a motor control interface operatively coupled to the microcontroller; an optically isolated digital input interface operatively coupled to the microcontroller; a digital output interface operatively coupled to the microcontroller; and instructions stored in the memory and executable by the microcontroller to instruct the unit to receive digital input via the optically isolated digital input interface from a machine and to output motor control signals via the motor control interface to at least one motor of the machine.

A circuit may be configured to reduce electrical signal degradation. The circuit may include a first trace and a second trace that may be broadside coupled between a first ground plane and a second ground plane. The first and second traces may be configured to carry first and second signals, respectively, of a differential signal. The circuit may also include a first dielectric material disposed between the first trace and the second trace. Further, the circuit may include a second dielectric material disposed between the first trace and the first ground plane and disposed between the second trace and the second ground plane. A difference between a first dielectric constant of the first dielectric material and a second dielectric constant of the second dielectric material may suppress a mode conversion of the differential signal from a differential mode to a common mode.

A coating can be provided on a substrate. Fabrication of the coating can include forming a solid layer in a specified region of the substrate while supporting the substrate in a coating system using a gas cushion. For example, a liquid coating can be printed over the specified region while the substrate is supported by the gas cushion. The substrate can be held for a specified duration after the printing the patterned liquid. The substrate can be conveyed to a treatment zone while supported using the gas cushion. The liquid coating can be treated to provide the solid layer including continuing to support the substrate using the gas cushion.

It is described a method for changing parameters for controlling a transfer of solder paste onto a printed circuit board (150, 250). The described method comprises (a) identifying first subareas (256, 258) of the printed circuit board (150, 250), which exhibit a first repeatability with respect to the amount of solder paste being supposed to be transferred onto the printed circuit board (150, 250), (b) identifying second subareas (252, 254) of the printed circuit board (150, 250), which exhibit a second repeatability with respect to the amount of solder paste being supposed to be transferred onto the printed circuit board (150, 250), wherein the first repeatability is smaller than the second repeatability, (c) transferring solder paste onto the printed circuit board (150, 250) at least at the second subareas (252, 254) of the printed circuit board (150, 250), (d) measuring the amount of solder paste which has been transferred to the second subareas (252, 254), and (e) changing the parameters for controlling a transfer of solder paste onto the printed circuit board (150, 250) in response to the measured amount of solder paste which has been transferred to the second subareas (252, 254). It is further described a corresponding processing device, a system comprising such a processing device and a computer program for controlling and/or for carrying out such a method.

A machine can include a first conveyor configured to receive and convey a circuit assembly; a second conveyor configured to receive and convey a circuit assembly; a first set of opposing side panels adjacent to opposing sides of the first conveyor; a second set of opposing side panels adjacent to opposing sides of the second conveyor; a first mechanism that selectively raises and lowers the first set of opposing side panels; and a second mechanism that selectively raises and lowers the second set of opposing side panels.

A method of depositing material on an electronic substrate with a dispensing system includes acquiring an image of a first feature of a first component and an adjacent second feature of a second component, performing a measure command to measure an actual distance of a gap between the first feature of the first component and the second feature of the second component, dividing the length of the gap into segments to determine a gap width for each segment, based on the gap width, determining a number of dots to be dispensed by the dispensing unit for each segment, and performing the dispense operation for each segment.

A printed circuit board includes, an insulating substrate, a metal conductor which is formed on the insulating substrate, a solder resist coating a part of the metal conductor, a scooped-out portion of the metal conductor formed in the vicinity of an end of the solder resist, and a metal layer coating the scooped-out portion.

A Three-dimensional (3D) printer includes a belt, a tray and a plurality of printing devices located on the belt. The tray is located on the belt and receives a printed circuit board (PCB). A sensor attached to the tray. The sensor is used to sense whether the PCB is located in the tray, when the PCB is located in the tray, the belt is driven by a driving device to transport the tray to be located below each of the plurality of printing devices. Each of the plurality of printing devices is used to print the PCB. The disclosure further offers a printing method for the PCB using the 3D printer.

A circuit may be configured to reduce electrical signal degradation. The circuit may include a first trace and a second trace that may be broadside coupled between a first ground plane and a second ground plane. The first and second traces may be configured to carry first and second signals, respectively, of a differential signal. The circuit may also include a first dielectric material disposed between the first trace and the second trace. Further, the circuit may include a second dielectric material disposed between the first trace and the first ground plane and disposed between the second trace and the second ground plane. A difference between a first dielectric constant of the first dielectric material and a second dielectric constant of the second dielectric material may suppress a mode conversion of the differential signal from a differential mode to a common mode.