A wearable static electricity removing device includes a portable device which has a metal sheet; a current limiter for limiting a current flow therethrough; .a high impedance resistor connected to the metal sheet; an impedance of the high impedance resistor being greater than that of the current limiter; a conductive wire having an end connected to the current limiter and the high impedance resistor; and another end of the conductive wire being grounded. In use, when the body of the user has static electricity, the static electricity will pass through the current limiter and then flows to the ground through the conductive wire so as to have the effect of removing the static electricity; and when the user contacts a high voltage which causes the current limiter to breakdown to protect the user, and the static electricity from the user flows through the high impedance resistor.

A mounting table is provided. The mounting table includes an electrostatic chuck configured to mount thereon a target object and attract and hold the target object using an electrostatic force, and a gas supply line configured to supply a gas to a gap between the target object mounted on the electrostatic chuck and the electrostatic chuck via the electrostatic chuck. The mounting table further includes at least one irradiation unit configured to irradiate light having a predetermined wavelength to the gas flowing through the gas supply line or to the gas supplied to the gap between the target object and the electrostatic chuck to ionize the gas.

A mounting table is provided. The mounting table includes an electrostatic chuck configured to mount thereon a target object and attract and hold the target object using an electrostatic force, and a gas supply line configured to supply a gas to a gap between the target object mounted on the electrostatic chuck and the electrostatic chuck via the electrostatic chuck. The mounting table further includes at least one irradiation unit configured to irradiate light having a predetermined wavelength to the gas flowing through the gas supply line or to the gas supplied to the gap between the target object and the electrostatic chuck to ionize the gas.

Various aspects of the disclosure provides for an ionized air blower that can be used to neutralize static charge on a target surface or provide a charge on the target surface. The ionized air blower may comprise a fan configured to generate airflow toward a target surface, an ionizer configured to produce positive ions and negative ions in the airflow, and control circuitry. The control circuitry is configured to control one or both of a speed of the airflow from the blower and ionization of the airflow. The ionization is performed by a selected one of ion imbalanced mode or ion balanced mode of the blower.

Various aspects of the disclosure provides for an ionized air blower that can be used to neutralize static charge on a target surface or provide a charge on the target surface. The ionized air blower may comprise a fan configured to generate airflow toward a target surface, an ionizer configured to produce positive ions and negative ions in the airflow, and control circuitry. The control circuitry is configured to control one or both of a speed of the airflow from the blower and ionization of the airflow. The ionization is performed by a selected one of ion imbalanced mode or ion balanced mode of the blower.

The present invention relates to a protective ionizing laminate (PIL) static eliminating device that uses a wide variety of laminate materials to protect ionizing points that eliminate static. In an embodiment, the protective encasement is made from laminate and in others it is made from a substrate onto which of electrically conductive or static dissipative material is printed or placed. The present invention includes a plurality of electrically conductive or static dissipative material or microfibers, wherein the plurality of electrically conductive or static dissipative material or microfibers forms a pattern and a ground in communication with the electrically conductive or static dissipative microfibers or material. The laminate materials form an encasement or enclosure of the electrically conductive or static dissipative microfibers or material and at least a portion of the ground. The PIL of the present invention includes an edge or slit in the enclosure that exposes the plurality of electrically conductive or static dissipative material or microfibers at the edge or slit to create a series of ionizing points. When air between the ionizing points and charged material passes by or near the PIL static eliminating device, the PIL sufficiently removes or reduces static charge from the passing material.

The present invention relates to a protective ionizing laminate (PIL) static eliminating device that uses a wide variety of laminate materials to protect ionizing points that eliminate static. In an embodiment, the protective encasement is made from laminate and in others it is made from a substrate onto which of electrically conductive or static dissipative material is printed or placed. The present invention includes a plurality of electrically conductive or static dissipative material or microfibers, wherein the plurality of electrically conductive or static dissipative material or microfibers forms a pattern and a ground in communication with the electrically conductive or static dissipative microfibers or material. The laminate materials form an encasement or enclosure of the electrically conductive or static dissipative microfibers or material and at least a portion of the ground. The PIL of the present invention includes an edge or slit in the enclosure that exposes the plurality of electrically conductive or static dissipative material or microfibers at the edge or slit to create a series of ionizing points. When air between the ionizing points and charged material passes by or near the PIL static eliminating device, the PIL sufficiently removes or reduces static charge from the passing material.

Embodiments of the present disclosure related to automated static control. A set of static sensor data may be obtained from two or more static sensors. The set of static sensor data may be analyzed to determine whether a static condition exists. In response to a determination that a static condition exists, a set of mobile static unit data may be collected from one or more mobile static units. The set of mobile static unit data may be analyzed to select a mobile static unit of the one or more mobile static units. An action may be transmitted to the selected mobile static unit, and the selected mobile static unit may be deployed to mitigate the static condition.

Embodiments of the present disclosure related to automated static control. A set of static sensor data may be obtained from two or more static sensors. The set of static sensor data may be analyzed to determine whether a static condition exists. In response to a determination that a static condition exists, a set of mobile static unit data may be collected from one or more mobile static units. The set of mobile static unit data may be analyzed to select a mobile static unit of the one or more mobile static units. An action may be transmitted to the selected mobile static unit, and the selected mobile static unit may be deployed to mitigate the static condition.

Embodiments of the present disclosure related to automated static control. A set of static sensor data may be obtained from two or more static sensors. The set of static sensor data may be analyzed to determine whether a static condition exists. In response to a determination that a static condition exists, a set of mobile static unit data may be collected from one or more mobile static units. The set of mobile static unit data may be analyzed to select a mobile static unit of the one or more mobile static units. An action may be transmitted to the selected mobile static unit, and the selected mobile static unit may be deployed to mitigate the static condition.