The present disclosure provides a surge protection device including a ceramic substrate (1), at least one pair of discharge electrodes (31) disposed on a surface of the ceramic substrate (1) so as to face each other at end portions thereof with a space in between, outer electrodes (32) electrically connected to the corresponding discharge electrodes (31), and a discharge auxiliary electrode (4) disposed between the end portions of the pair of discharge electrodes (31) The discharge auxiliary electrode (4) contains crystalized glass and particles of conductive powder (40) dispersed apart from each other in the crystalized glass.

An electrostatic protection system for hand-held wireless vacuum cleaner comprises an electrostatic collecting unit and an electrostatic dissipating unit. The electrostatic collecting unit comprises an electrostatic collecting device; the electrostatic dissipating unit comprises a battery pack assembly, and the electrostatic collecting device is electrically connected to a negative electrode of the battery pack assembly. The electrostatic collecting unit is electrically connected to the electrostatic dissipating unit, and an electrostatic charge is transmitted to the negative electrode of the battery pack assembly through the electrostatic collecting device to realize electrostatic charge transfer. The electrostatic protection system effectively transfers the accumulated electrostatic charge, thereby avoiding the phenomenon of electrostatic shock, e.g. on the human's hand, and also protecting important components inside a machine from electrostatic damage.

A protection structure includes a substrate, a signal wire pattern, a protective ring and micro-blocks. The substrate has a touch sensing pattern including sensing strings. The signal wire pattern has conductive wires. Each conductive wire electrically connects one of the sensing strings to a signal processor. The protective ring is formed at a peripheral zone of the substrate and around the touch sensing pattern. The micro-blocks are disposed in the protective ring and have electric conductivity. A gap is disposed between every adjacent two of the micro-blocks for insulation.

A protection structure includes a substrate, a signal wire pattern, a protective ring and micro-blocks. The substrate has a touch sensing pattern including sensing strings. The signal wire pattern has conductive wires. Each conductive wire electrically connects one of the sensing strings to a signal processor. The protective ring is formed at a peripheral zone of the substrate and around the touch sensing pattern. The micro-blocks are disposed in the protective ring and have electric conductivity. A gap is disposed between every adjacent two of the micro-blocks for insulation.

There is provided an electrostatic attraction device having an electrostatic chuck in which an electrode and a heater are embedded in a dielectric. The device comprises: a DC power source unit having a DC power source configured to supply a DC power to the electrode; a first neutralizing circuit connected to a power supply path between the DC power source and the electrode; and a second neutralizing circuit connected to a power supply path between the first neutralizing circuit and the electrode. The first neutralizing circuit has a first ground relay that connects and disconnects the electrode and the ground via a voltage-drop resistance member, and the second neutralizing circuit has an isolation relay that connects and disconnects the first neutralizing circuit and the second neutralizing circuit, and a second ground relay that is connected to a power supply path between the isolation relay and the electrode and connects and disconnects the electrode and the ground side without going through a resistance member.

There is provided an electrostatic attraction device having an electrostatic chuck in which an electrode and a heater are embedded in a dielectric. The device comprises: a DC power source unit having a DC power source configured to supply a DC power to the electrode; a first neutralizing circuit connected to a power supply path between the DC power source and the electrode; and a second neutralizing circuit connected to a power supply path between the first neutralizing circuit and the electrode. The first neutralizing circuit has a first ground relay that connects and disconnects the electrode and the ground via a voltage-drop resistance member, and the second neutralizing circuit has an isolation relay that connects and disconnects the first neutralizing circuit and the second neutralizing circuit, and a second ground relay that is connected to a power supply path between the isolation relay and the electrode and connects and disconnects the electrode and the ground side without going through a resistance member.

A wireless anti-static device is disclosed, including an electronic sensing circuit that measures the polarity and electrostatic potential of the subject relative to its surroundings. Ion guns of positive and negative polarities are able to transfer an arbitrary quantity and polarity of charge from the subject by ejecting ionized air molecules into the surrounding environment. A control unit is programmed to trigger the appropriate ion gun when a corresponding charge is measured on the body, in order to continually maintain the net charge on the body below a desired threshold. The subject is thus effectively grounded relative to its environment without requiring physical tethers to ground.

A wireless anti-static device is disclosed, including an electronic sensing circuit that measures the polarity and electrostatic potential of the subject relative to its surroundings. Ion guns of positive and negative polarities are able to transfer an arbitrary quantity and polarity of charge from the subject by ejecting ionized air molecules into the surrounding environment. A control unit is programmed to trigger the appropriate ion gun when a corresponding charge is measured on the body, in order to continually maintain the net charge on the body below a desired threshold. The subject is thus effectively grounded relative to its environment without requiring physical tethers to ground.

A display module is disclosed. The display module includes: a display panel body; a backplate; a composite functional layer disposed on a back side of the backplate; and an electrostatic discharging part including an electrostatic conductive element and an electrostatic discharging element connected to the electrostatic conductive element. Wherein, the electrostatic conductive element is in contact with the display panel body and/or the backplate, and the electrostatic discharging element is in electrical contact with the metal layer of the composite functional layer. Therefore, fluctuations of driving voltages caused by static electricity can be eliminated.

A display module is disclosed. The display module includes: a display panel body; a backplate; a composite functional layer disposed on a back side of the backplate; and an electrostatic discharging part including an electrostatic conductive element and an electrostatic discharging element connected to the electrostatic conductive element. Wherein, the electrostatic conductive element is in contact with the display panel body and/or the backplate, and the electrostatic discharging element is in electrical contact with the metal layer of the composite functional layer. Therefore, fluctuations of driving voltages caused by static electricity can be eliminated.