A processing liquid used in a substrate liquid processing apparatus can be supplied in a constant amount with high accuracy. A substrate liquid processing apparatus A1 includes a storage line 61 configured to store a processing liquid therein; an introduction line 62 configured to introduce the processing liquid into the storage line 61; a discharge line 63 configured to discharge the processing liquid from the storage line 61; and a gas supply unit 65 configured to perform a strickling of the processing liquid by jetting a gas to a surface of the processing liquid stored in the storage line 61.

A sensor for the continuous in-situ analysis of an aerosol flow for measuring the mass of the micron/submicron particles suspended in the air flow, including an aeraulic sorter allowing the particles to be sorted according to their size with an impactor body with a cascade of one or more stages; at least one MEMS microbalance per stage, with an oscillating silicon membrane located on the impaction zone of the particles; processor connected to each MEMS microbalance to determine the mass of all the particles on the impaction zone; a system for cleaning the MEMS microbalances allowing the evacuation of the particles from the MEMS microbalances; means for driving the aerosol flow.

A sensor for the continuous in-situ analysis of an aerosol flow for measuring the mass of the micron/submicron particles suspended in the air flow, including an aeraulic sorter allowing the particles to be sorted according to their size with an impactor body with a cascade of one or more stages; at least one MEMS microbalance per stage, with an oscillating silicon membrane located on the impaction zone of the particles; processor connected to each MEMS microbalance to determine the mass of all the particles on the impaction zone; a system for cleaning the MEMS microbalances allowing the evacuation of the particles from the MEMS microbalances; means for driving the aerosol flow.

An impactor, system and method for performing real-time measurements of particles in aerosol gases. The impactor comprises a plurality of cascading stages having impaction plates, mass-measurement mechanisms retained on the impaction plates, and a nozzle plate. A signal line associated with each of the plurality of cascading stages is configured to relay signals from the mass-measurement mechanism of the associated stage to a computer-based system configured to receive the transmitted signals from the signal lines, and to correlate changes in the resonant frequencies to particle concentrations in real time.

An impactor, system and method for performing real-time measurements of particles in aerosol gases. The impactor comprises a plurality of cascading stages having impaction plates, mass-measurement mechanisms retained on the impaction plates, and a nozzle plate. A signal line associated with each of the plurality of cascading stages is configured to relay signals from the mass-measurement mechanism of the associated stage to a computer-based system configured to receive the transmitted signals from the signal lines, and to correlate changes in the resonant frequencies to particle concentrations in real time.

A sensor for the continuous in-situ analysis of an aerosol flow for measuring the mass of the micron/submicron particles suspended in the air flow, including an aeraulic sorter allowing the particles to be sorted according to their size with an impactor body with a cascade of one or more stages; at least one MEMS microbalance per stage, with an oscillating silicon membrane located on the impaction zone of the particles; processor connected to each MEMS microbalance to determine the mass of all the particles on the impaction zone; a system for cleaning the MEMS microbalances allowing the evacuation of the particles from the MEMS microbalances; means for driving the aerosol flow.

A sensor for the continuous in-situ analysis of an aerosol flow for measuring the mass of the micron/submicron particles suspended in the air flow, including an aeraulic sorter allowing the particles to be sorted according to their size with an impactor body with a cascade of one or more stages; at least one MEMS microbalance per stage, with an oscillating silicon membrane located on the impaction zone of the particles; processor connected to each MEMS microbalance to determine the mass of all the particles on the impaction zone; a system for cleaning the MEMS microbalances allowing the evacuation of the particles from the MEMS microbalances; means for driving the aerosol flow.

The present invention is a computer method for generating a set of assembly illustrations, comprising: accessing a model frame wherein the model frame includes at least one roof joist assembly; analyzing the roof joist assembly, wherein a set of members are identified which comprise the roof joist; accessing the set of members and individually analyzing each members properties and coordinates and relationship to all interfacing members; transitioning the model frame roof joist from a first state to a second state, wherein an analysis is performed on the conversion based on the order and process of the transition data; and analyzing the transition data for member interfacing, and processing the transition data relative to the member interfacing to identify an assembly process for the roof joist; and generating to be displayed on a display module, a set of drawings which represent the assembly process of the roof joist.

The present invention is a computer method for generating a set of assembly illustrations, comprising: accessing a model frame wherein the model frame includes at least one floor joist assembly; analyzing the floor joist assembly, wherein a set of members are identified which comprise the floor joist; accessing the set of members and individually analyzing each members properties and coordinates and relationship to all interfacing members; transitioning the model frame floor joist from a first state to a second state, wherein an analysis is performed on the conversion based on the order and process of the transition data; and analyzing the transition data for member interfacing, and processing the transition data relative to the member interfacing to identify an assembly process for the floor joist; and generating to be displayed on a display module, a set of drawings which represent the assembly process of the floor joist.

The present invention is a computer method for generating a set of assembly illustrations, comprising: accessing a model frame wherein the model frame includes at least one wall panel assembly; analyzing the wall panel assembly, wherein a set of members are identified which comprise the wall panel; accessing the set of members and individually analyzing each members properties and coordinates and relationship to all interfacing members; transitioning the model frame wall panel from a first state to a second state, wherein an analysis is performed on the conversion based on the order and process of the transition data; and analyzing the transition data for member interfacing, and processing the transition data relative to the member interfacing to identify an assembly process for the wall panel; and generating to be displayed on a display module, a set of drawings which represent the assembly process of the wall panel.