Интернаука - Интернаука №16 ((часть2) 2020

– 2019. – № 1

4. Патентная аппликация США No20180321666, 08.11.2018. METHODS AND SYSTEMS FOR EQUIPMENT

MONITORING IN AN INTERNET OF THINGS MINING ENVIRONMENT / Cella; Charles Howard; et al.

5. Патентная аппликация США No20180284753, 04.10.2018. METHODS AND SYSTEMS FOR DATA STORAGE AND COMMUNICATION IN AN INTERNET OF THINGS CHEMICAL PRODUCTION PROCESS / Cella; Charles Howard; et al.

6. Патентная аппликация США No20060036394, 16.02.2006. Universal and integrated wafer testing real-time monitoring software system and its open system architecture / Chen; Wen-Ling; et al.

7. Патентная аппликация США No20070156272, 05.07.2007. Integrated configuration, flow and execution system for semiconductor device experimental flows and production flows / Winstead; Charles H.; et al.

8. Патентная аппликация США No20060064188, 23.03.2006. Process-state management system, management server and control server adapted for the system, method for managing process-states, method for manufacturing a product, and computer program product for the management server / Ushiku; Yukihiro; et al.

9. Патентная аппликация США No20170004985, 05.01.2017. PRODUCTION SYSTEM FOR PRINTING ELECTRONIC DEVICES / NISHI; Shinichi; et al.

10. Патентная аппликация США No20180133677, 17.05.2018. APPARATUS FOR A MASS PRODUCTION OF

MONODISPERSE BIODEGRADEABLE POLYMER-BASED MICROSPHERES AND A MULTI-CHANNEL

FORMING DEVICE INCORPORATABLE THEREIN / KIM; Ju Hee

11. Патентная аппликация США No20150066592, 05.03.2015. METHODS OF SEMICONDUCTOR MANUFACTURING AND SUPPLY CHAIN MANAGEMENT SYSTEMS / Ehm; Hans; et al.

12. Патентная аппликация США No20080008837, 10.01.2008. SUBSTRATE PROCESSING APPARATUS AND

SUBSTRATE PROCESSING METHOD FOR HEAT-TREATING SUBSTRATE / SHIBA; Yasuhiro; et al.

13. Патентная аппликация США No20050264777, 01.12.2005. High speed lithography machine and method / Gardner, Steven D.; et al.

Приложение 1.

20180321666

United States Patent Application

Kind Code

A1

Cella; Charles Howard; et al.

November 8, 2018

METHODS AND SYSTEMS FOR EQUIPMENT MONITORING IN AN INTERNET OF THINGS MINING

ENVIRONMENT

Abstract

An apparatus, methods, and systems for data collection in a production environment are described. The system may include a data collector communicatively coupled to a plurality of input channels, wherein a first subset of the plurality of input channels are connected to a first set of sensors measuring operational parameters from a production component, a data storage structured to store a plurality of collector routes and collected data, a data acquisition circuit structured to interpret a plurality of detection values from the collected data of the production component, and a data analysis circuit structured to analyze the collected data and evaluate a first collection routine of the data collector based on the analyzed collected data, wherein based on the analyzed collected data the data collector makes a collection routine change.

23

Журнал «Интернаука»

№ 16 (145), часть 2, 2020 г.

Приложение 2

United States Patent Application

20180284753

Kind Code

A1

Cella; Charles Howard; et al.

October 4, 2018

METHODS AND SYSTEMS FOR DATA STORAGE AND COMMUNICATION IN AN INTERNET OF

THINGS CHEMICAL PRODUCTION PROCESS

Abstract

A system, method and apparatus for data collection related to a chemical production process are described. The system may include a cross point switch including a plurality of inputs and a plurality of outputs, a plurality of sensors operatively coupled to at least one of a plurality of components of the chemical production process, a sensor data storage profile circuit structured to determine a data storage profile, wherein the cross point switch is responsive to the data storage profile to selectively couple at least one of the plurality of inputs to at least one of the plurality of outputs, a sensor communication circuit communicatively coupled to the plurality of outputs of the cross point switch, and a sensor data storage implementation circuit structured to store at least a portion of the plurality of sensor data values in re-sponse to the data storage profile.

Приложение 3

United States Patent Application

20060036394

Kind Code

A1

Chen; Wen-Ling; et al.

February 16, 2006

Universal and integrated wafer testing real-time monitoring software system and its open system architecture Abstract

A wafer testing real-time monitoring software system and its unique open software architecture which achieves re-al-time monitoring of wafer test results and on -line changing of externally hooked software to satisfy customer needs without changing its main program. The software structure receives and processes binary files from different probers and converts these into readable ASCII files. The system consists of four software programs that can operate independently. These programs are an automatic transfer program, a program which converts wafer test results from a binary file to an ASCII file, a program which receives the ASCII files and performs wafer map editing, and an auto-ftp program which automatically scans data and sends data to remote locations. Additionally, multiple workstations can process data from probers simultaneously. The on -line monitor on a production line can see production results from multiple major workstations through the network drive and drive mapping functions.

Приложение 4

United States Patent Application

20070156272

Kind Code

A1

Winstead; Charles H.; et al.

July 5, 2007

Integrated configuration, flow and execution system for semiconductor device experimental flows and production flows

Abstract

According to embodiments of the invention, an integrated configuration, flow and execution systems (ICFES) may be used to specify, control and record a history of processing of both semiconductor device experimental lots and pro-

duction lots of wafers. Moreover, the system allows combining of one or more partial flows of pre-existing flow blocks, and special processing into another processing flow block. A lot plan can be created that includes the flow block, and the lot plan can be updated to include partial flows and special processing before or during processing of the lot plan.

24

Журнал «Интернаука»

№ 16 (145), часть 2, 2020 г.

Приложение 5

United States Patent Application

20060064188

Kind Code

A1

Ushiku; Yukihiro; et al.

March 23, 2006

Process-state management system, management server and control server adapted for the system, method for managing process-states, method for manufacturing a product, and computer program product for the management server Abstract

A process-state management system encompasses: a plurality of production machines; a control server configured to collectively control at least part of the production machines; a management server including a data-linking module configured to link operation-management data of the production machines with corresponding management information transmitted from the control server, respectively, the management server analyze the operation-management data linked with the management information with a common analysis application; and a management database configured to store the operation-management data linked with the management information.

Приложение 6

United States Patent Application

20170004985

Kind Code

A1

NISHI; Shinichi; et al.

January 5, 2017

PRODUCTION SYSTEM FOR PRINTING ELECTRONIC DEVICES

Abstract

An object of the present invention is to provide a printing production line system for an electronic device, the printing production line system that can achieve prevention of defective products caused by dust generated by a printing method and increase electronic device productivity, and a transport chamber provided with a robot transport line 100 in which a self-traveling robot 111, 112 that transports a base material 15 in a sheet-fed manner in a free state travels is provided, a plurality of processing chambers 6 for forming an electronic device on the base material 15 by printing are provided on at least one side of the transport chamber, a base material transfer area 601 that performs loading of the base material 15 to the processing chamber 6 from the self-traveling robot 111, 112 and unloading of the base material to the self-traveling robot 111, 112 from the processing chamber 6 is provided between the transport chamber and each processing chamber 6, the transport chamber and the base material transfer area 601 communicate with each other through an opening 602 in which a one-way air flow moving to the side where the processing chamber 6 is located from the side where the transport chamber is located is formed, and the one-way air flow in the opening 602 is formed by making an adjustment such that the air pressure in the transport chamber becomes higher than the air pressure in the base material transfer area 601.

Приложение 7

United States Patent Application

20180133677

Kind Code

A1

KIM; Ju Hee

May 17, 2018

APPARATUS FOR A MASS PRODUCTION OF MONODISPERSE BIODEGRADEABLE POLYMER-BASED

MICROSPHERES AND A MULTI-CHANNEL FORMING DEVICE INCORPORATABLE THEREIN

Abstract

Provided is an apparatus for a mass production of microspheres and a multichannel forming device incorporatable therein. The apparatus comprises a multi-channel microsphere forming unit, a first source material reservoir containing the first source material and in fluid communication with the plurality of first microchannels, a second source material reservoir containing the second source material and in fluid communication with the plurality of second microchannels, a flow control unit configured to supply a first gas to the first source material reservoir at a first source material flow rate and to supply a second gas to a second source material reservoir at a second source material flow rate and a product reservoir for accommodating the microspheres formed from the multi-channel forming unit.