OPTICAL MEASUREMENT APPARATUS AND OPTICAL MEASUREMENT METHOD

Organization Name

Samsung Electronics Co., Ltd.

Inventor(s)

DEOKHYEON Kwon of HWASEONG-SI (KR)

JUA Ryu of SEONGNAM-SI (KR)

JUHYUN Park of SEOUL (KR)

KIDOO Kim of HWASEONG-SI (KR)

HYUNOK Kim of SUWON-SI (KR)

SUNAH Park of HWASEONG-SI (KR)

HYUNJUNG Choi of HWASEONG-SI (KR)

OPTICAL MEASUREMENT APPARATUS AND OPTICAL MEASUREMENT METHOD - A simplified explanation of the abstract

This abstract first appeared for US patent application 17815512 titled 'OPTICAL MEASUREMENT APPARATUS AND OPTICAL MEASUREMENT METHOD

Simplified Explanation

The patent application describes an optical measurement method that uses light to detect and measure the concentration of particles and gases in an aerosol sample. Here are the key points:

• Light is generated and directed into a light path cell.
• The light is continuously reflected between two high reflection mirrors within the light path cell.
• An optical signal is detected from the aerosol sample within the light path.
• The optical signal is separated into a particle signal and a gas signal using statistical methodology.
• The particle signal is used to calculate the particle concentration using an assumption of an optical particle counter (OPC).
• The gas signal is used to calculate the gas concentration using optical characteristic data of the gas.

Potential applications of this technology:

• Environmental monitoring: This method can be used to measure the concentration of particles and gases in the air, providing valuable data for assessing air quality and pollution levels.
• Industrial processes: The technology can be applied in various industries to monitor and control the concentration of particles and gases in manufacturing processes, ensuring compliance with regulations and optimizing production efficiency.
• Health and safety: The method can be used in healthcare settings to monitor the concentration of airborne particles and gases, helping to identify potential health risks and ensure a safe environment for patients and healthcare workers.

Problems solved by this technology:

• Accurate measurement: The method provides a reliable and accurate way to measure the concentration of particles and gases in an aerosol sample, overcoming the limitations of traditional measurement techniques.
• Separation of signals: By using statistical methodology, the optical signal can be effectively separated into particle and gas signals, allowing for precise calculation of their respective concentrations.
• Real-time monitoring: The technology enables real-time monitoring of particle and gas concentrations, providing timely information for decision-making and intervention.

Benefits of this technology:

• Improved accuracy: The method offers improved accuracy compared to traditional measurement techniques, ensuring reliable and precise results.
• Efficiency: By continuously reflecting the light within the light path cell, the method allows for efficient and rapid measurement of particle and gas concentrations.
• Versatility: The technology can be applied in various settings and industries, making it a versatile solution for measuring and monitoring aerosol samples.

Original Abstract Submitted

In an optical measurement method, light is directed from a light generator to a light path cell. A light path is generated by continuously reflecting the light between first and second high reflection mirrors within a light path cell that face to each other. An optical signal is detected from an aerosol sample present within a range of the light path. The optical signal is separated into a particle signal and a gas signal by using a statistical methodology. A particle concentration is calculated from the particle signal by using an assumption of an optical particle counter (OPC). A gas concentration is calculated from the gas signal by using optical characteristic data of gas.