A method for measuring the attraction propensity of fabric including the steps of charging a neutralized test fabric, optionally by contacting with a charging fabric, presenting the charged test fabric a predetermined distance from a static-influenced agent such that at least a portion of the static-influenced agent attaches to the charged test fabric, and determining the quantity of attached static-influenced agent.

A triboelectric probe (100), and a dust removal system and a monitoring method, device, and apparatus therefor, being used for solving the technical problem of reducing the number of triboelectric probes (100) used for different independent detection regions. The triboelectric probe (100) comprises a probe (110); the probe (110) comprises a sensing part (111) which comprises at least two sensing elements (111a) connected to form a current path or being separated, the at least two sensing elements (111a) are used for being respectively arranged in different independent detection regions of a target space, and when particles in any independent detection region pass through the corresponding sensing element (111a), a current signal is generated on the corresponding sensing element (111a); and the probe (110) also comprises an output part (112) which is simultaneously connected to and conducted with the at least two sensing elements (111a) separated in the sensing part (111) or is served by any one sensing element (111a) among the at least two sensing elements (111a) in the sensing part (111) which are connected to form a current path, and is used for outputting a current signal generated by each sensing element (111a) in the sensing part (111). The improved triboelectric probe (100) can detect different independent detection regions.

A remote detector detects the presence of dielectric materials, including energetic materials. The remote detector includes a center beam secured in a pivot mount, at least one collector secured to the center beam at a proximal end via the pivot mount, and an analog matching filter coupled with the center beam via a circuit. The analog matching filter contains a replicate matching material configured to match a dipole field of a target material. In the presence of a target material, the replicate matching material causes displacement of the center beam via a dielectrokinesis (phoresis) force.

A remote detector detects the presence of dielectric materials, including energetic materials. The remote detector includes a center beam secured in a pivot mount, at least one collector secured to the center beam at a proximal end via the pivot mount, and an analog matching filter coupled with the center beam via a circuit. The analog matching filter contains a replicate matching material configured to match a dipole field of a target material. In the presence of a target material, the replicate matching material causes displacement of the center beam via a dielectrokinesis (phoresis) force.

An active fluid static elimination system installed in a fluid transportation pipeline includes a solenoid valve, an electrostatic measuring device, a fluid destaticizer, and a controller. The solenoid valve is connected to a connecting port of the fluid transportation pipeline, and the electrostatic measuring device is used to measure an electrostatic value of a fluid in the fluid transportation pipeline. The fluid destaticizer is connected to the solenoid valve, and the controller is connected to the electrostatic measuring device and the solenoid valve. The solenoid valve is opened to allow the fluid passing through the fluid destaticizer to eliminate the electrostatic charge of the fluid when the controller determines that the electrostatic value measured by the electrostatic measuring device is greater than a predetermined value.

An active fluid static elimination system installed in a fluid transportation pipeline includes a solenoid valve, an electrostatic measuring device, a fluid destaticizer, and a controller. The solenoid valve is connected to a connecting port of the fluid transportation pipeline, and the electrostatic measuring device is used to measure an electrostatic value of a fluid in the fluid transportation pipeline. The fluid destaticizer is connected to the solenoid valve, and the controller is connected to the electrostatic measuring device and the solenoid valve. The solenoid valve is opened to allow the fluid passing through the fluid destaticizer to eliminate the electrostatic charge of the fluid when the controller determines that the electrostatic value measured by the electrostatic measuring device is greater than a predetermined value.

A streaming current measurement flow cell, free from potential piston-to-electrode contact, with a flexible, but close-fitting piston and sleeve set, wherein a housing-defined bushing, as it encircles the piston's active segment near its upper end, does so with a short, cylindrical sidewall, the inside diameter of which, in comparison to the active segment's diameter, creates a narrower—but by only 0.002 inch—capillary-sized flow channel between the bushing and the active segment than exists between it and the sleeve. Even so, physical contact between piston and sleeve—a major wear factor—is completely eliminated; and larger particles known to scratch/gouge dielectric surfaces are kept out of the piston/sleeve flow channel. Moreover, a limitation on the piston's downward travel wherein the active segment's upper end is brought just flush with the upper electrode's flat, annular face makes possible a novel system, critical in self-cleaning this electrode where its inner edge and setback are exposed atop the bushing.

A streaming current measurement flow cell, free from potential piston-to-electrode contact, with a flexible, but close-fitting piston and sleeve set, wherein a housing-defined bushing, as it encircles the piston's active segment near its upper end, does so with a short, cylindrical sidewall, the inside diameter of which, in comparison to the active segment's diameter, creates a narrower—but by only 0.002 inch—capillary-sized flow channel between the bushing and the active segment than exists between it and the sleeve. Even so, physical contact between piston and sleeve—a major wear factor—is completely eliminated; and larger particles known to scratch/gouge dielectric surfaces are kept out of the piston/sleeve flow channel. Moreover, a limitation on the piston's downward travel wherein the active segment's upper end is brought just flush with the upper electrode's flat, annular face makes possible a novel system, critical in self-cleaning this electrode where its inner edge and setback are exposed atop the bushing.

Methods and systems are provided for accurate and efficient identification and quantification of proteins. In an aspect, disclosed herein is a method for identifying a protein in a sample of unknown proteins, comprising receiving information of a plurality of empirical measurements performed on the unknown proteins; comparing the information of empirical measurements against a database comprising a plurality of protein sequences, each protein sequence corresponding to a candidate protein among a plurality of candidate proteins; and for each of one or more of the plurality of candidate proteins, generating a probability that the candidate protein generates the information of empirical measurements, a probability that the plurality of empirical measurements is not observed given that the candidate protein is present in the sample, or a probability that the candidate protein is present in the sample; based on the comparison of the information of empirical measurements against the database.

A solid-liquid contact electrification-based self-driving chemical sensor includes a container, a contact liquid, an electrode, a solid triboelectric layer, a rectifier, a load, and a displacement device. The contact liquid is placed in the container. The electrode may be actively or passively moved into the container to be immersed in or emerged from the contact liquid. The solid triboelectric layer surrounds and covers a surface of the electrode. The solid triboelectric layer includes a sensing layer which becomes a reacted sensing layer by reacting to a target analyte. The rectifier and the load are connected to the electrode. The displacement device is connected to the electrode or the container to perform a periodic reciprocating motion, so that the solid triboelectric layer is in contact with and separated from the contact liquid, thereby generating a surface charge transfer to generate an electrical output signal.