Process and plant for particulate matter along a conveyor system of products, said plant having a collection system which sucks a carrier gas flow and demarcates, in use, a suction chamber, namely a closed volume, with said product which advances in an advancing direction on an advancing plane; the separation plant having a separation system which is connected to said collection system and gets, in use, said carrier gas flow and particulate matter; wherein said separation system separates particulate matter from the carrier gas flow.

Process and plant for particulate matter along a conveyor system of products, said plant having a collection system which sucks a carrier gas flow and demarcates, in use, a suction chamber, namely a closed volume, with said product which advances in an advancing direction on an advancing plane; the separation plant having a separation system which is connected to said collection system and gets, in use, said carrier gas flow and particulate matter; wherein said separation system separates particulate matter from the carrier gas flow.

To provide a method for quantitatively and stably feeding fine powder and a system for carrying out the method. The present invention is characterized in that a gas transfer type fine powder quantitative feeding method for quantitatively transferring and feeding fine powder filled in a gas transfer type fine powder quantitative feeder to a fine powder using device by a carrier gas, wherein

when a mixed fluid of the fine powder and the carrier gas is transferred from the gas transfer type fine powder quantitative feeder to the fine powder using device, a water content in the carrier gas is adjusted to suppress an amount of static electricity that is generated in the mixed fluid.

To provide a method for quantitatively and stably feeding fine powder and a system for carrying out the method. The present invention is characterized in that a gas transfer type fine powder quantitative feeding method for quantitatively transferring and feeding fine powder filled in a gas transfer type fine powder quantitative feeder to a fine powder using device by a carrier gas, wherein

when a mixed fluid of the fine powder and the carrier gas is transferred from the gas transfer type fine powder quantitative feeder to the fine powder using device, a water content in the carrier gas is adjusted to suppress an amount of static electricity that is generated in the mixed fluid.

An apparatus for filling a wafer with glass powder includes a supporting device for supporting a wafer, a feeding device and a scraping device, where the feeding device and the scraping device are both provided on an upper side of the supporting device; a lower side of the feeding device is provided with a fetching part, and the feeding device drives the fetching part to move; a lower side of the scraping device is provided with a scraper, and the scraping device drives the scraper to move. After the feeding device evenly applies the glass powder to the wafer through the fetching part, the scraping device removes an excess of the glass powder on the wafer through the scraper to ensure an appropriate amount of glass powder on the wafer, avoiding complex subsequent processing due to excessive glass powder, and avoiding uneven glass powder distribution.

An apparatus for filling a wafer with glass powder includes a supporting device for supporting a wafer, a feeding device and a scraping device, where the feeding device and the scraping device are both provided on an upper side of the supporting device; a lower side of the feeding device is provided with a fetching part, and the feeding device drives the fetching part to move; a lower side of the scraping device is provided with a scraper, and the scraping device drives the scraper to move. After the feeding device evenly applies the glass powder to the wafer through the fetching part, the scraping device removes an excess of the glass powder on the wafer through the scraper to ensure an appropriate amount of glass powder on the wafer, avoiding complex subsequent processing due to excessive glass powder, and avoiding uneven glass powder distribution.

A vacuum nozzle includes a main body (12) and at least one auxiliary body (22). The main body has a first open end (16) and a second open end (18). The first open end is coupleable to a vacuum hose (2) and the second open end is configured for receiving materials to be transferred. The auxiliary body (130) has a first auxiliary opening (136) and a second auxiliary opening (138). The first auxiliary opening is positioned closer to the first open end of the main body than the second open end of the main body. The second auxiliary opening covers a portion of the second open end of the main body. The auxiliary body provides a dedicated auxiliary passageway for providing a consistent flow of air to the second open end of the main body when the vacuum nozzle is in use.

A vacuum nozzle includes a main body (12) and at least one auxiliary body (22). The main body has a first open end (16) and a second open end (18). The first open end is coupleable to a vacuum hose (2) and the second open end is configured for receiving materials to be transferred. The auxiliary body (130) has a first auxiliary opening (136) and a second auxiliary opening (138). The first auxiliary opening is positioned closer to the first open end of the main body than the second open end of the main body. The second auxiliary opening covers a portion of the second open end of the main body. The auxiliary body provides a dedicated auxiliary passageway for providing a consistent flow of air to the second open end of the main body when the vacuum nozzle is in use.

Process and plant for particulate matter along a conveyor system of products, said plant having a collection system which sucks a carrier gas flow and demarcates, in use, a suction chamber, namely a closed volume, with said product which advances in an advancing direction on an advancing plane; the separation plant having a separation system which is connected to said collection system and gets, in use, said carrier gas flow and particulate matter; wherein said separation system separates particulate matter from the carrier gas flow.

Process and plant for particulate matter along a conveyor system of products, said plant having a collection system which sucks a carrier gas flow and demarcates, in use, a suction chamber, namely a closed volume, with said product which advances in an advancing direction on an advancing plane; the separation plant having a separation system which is connected to said collection system and gets, in use, said carrier gas flow and particulate matter; wherein said separation system separates particulate matter from the carrier gas flow.