KR-20260064896-A - Sensors with On-Device AI Function Integrated Noise Vibration Impact Sensor for Wired and Wireless Communication Drive, its system, and its operation method

Abstract

The present invention relates to a noise vibration impact sensor with an integrated wired/wireless communication drive and on-device AI function, a system thereof, and a method of operation thereof. By introducing smart functions and utilizing machine learning via an Artificial Neural Network (ANN), it scans (captures data) the noise, vibration, and impact status of a measurement target within seconds, organizes and labels the data, distinguishes between normal and abnormal conditions regarding abnormal noise, vibration, and impact, derives normal and abnormal results, and predicts accidents, thereby enabling the prevention and avoidance of social and natural disasters affecting industrial infrastructure. The method of operation of a monitoring noise, vibration, and shock sensor according to the present invention comprises: (a) a step in which, when a noise, vibration, and shock source is input through a microphone and a MEMS-based 3-axis accelerometer and a running button of an external interface is interrupted, the AI of the on-device AI noise, vibration, and shock sensor operates to compute and store data of the noise, vibration, and shock source using an ANN algorithm of a storage device; (b) a step in which the noise, vibration, and shock state of a measurement target is scanned through machine learning using the ANN algorithm, and data filtering and labeling are performed, and normal and abnormal conditions regarding abnormal noise, vibration, and shock are distinguished through machine learning, and normal and abnormal results are derived to predict an accident; and (c) a step in which the normal and abnormal result data from the on-device AI noise, vibration, and shock sensor is transmitted to an edge gateway device via wired or wireless communication such as wireless LAN, Bluetooth, or USB.

Inventors

• 강언욱
• 박상규
• 정순현
• 안덕환

Assignees

• 주식회사 레스코

Dates

Publication Date

20260508

Application Date

20241030

Claims (7)

1. In the method of operation of a noise, vibration, and shock sensor, (a) A step in which, when a noise, vibration, and shock source is input through a microphone and a MEMS-based 3-axis accelerometer and the running button of an external interface is interrupted, the AI of the on-device AI noise, vibration, and shock sensor operates to compute and store data of the noise, vibration, and shock source using an ANN algorithm of a storage device; (b) a step of scanning the noise, vibration, and shock conditions of a measurement target through machine learning using the above ANN algorithm, filtering and labeling the data, distinguishing between normal and abnormal conditions regarding abnormal noise, vibration, and shock through machine learning, deriving normal and abnormal results to predict an accident; and (c) A step of transmitting normal and abnormal result data from the above-described on-device AI noise, vibration, and shock sensor to an edge gateway device via wired/wireless communication such as wireless LAN, Bluetooth, or USB; A method of operation of a noise, vibration, and shock sensor including
2. In the method of operation of a noise, vibration, and shock sensor, (a) A step in which, when a noise, vibration, and shock source is input through a MEMS-based 3-axis accelerometer and the running button of an external interface is interrupted, the AI of the on-device AI vibration and shock sensor operates to compute and store data of the noise, vibration, and shock source using an ANN algorithm of a storage device; (b) a step of scanning the noise, vibration, and shock conditions of a measurement target through machine learning using the above ANN algorithm, filtering and labeling the data, distinguishing between normal and abnormal conditions regarding abnormal noise, vibration, and shock through machine learning, deriving normal and abnormal results to predict an accident; and (c) A step of connecting to the above-described on-device AI noise, vibration, and shock sensor via WAN, LAN, Bluetooth, or USB to a smart terminal, tablet PC, laptop, or PC to monitor the sensor's detection and result data in real time, and to set and verify the data; A method of operation of a noise, vibration, and shock sensor including
3. In claim 1 or claim 2, The above-mentioned on-device AI noise, vibration, and shock sensor is, By applying machine learning to reference data and changed data of normal-state noise, vibration, and shock, distinguishing between normal and abnormal conditions regarding abnormal noise, vibration, and shock and deriving normal and abnormal results, Operation method of noise, vibration, and shock sensors.
4. In claim 1 or claim 2, The above-mentioned on-device AI noise, vibration, and shock sensor is, The above machine learning operation and the above normal and abnormal results are distinguished by color and displayed via an indicator LED, and in the event of an abnormal result, it is indicated by a flashing red light and provided as a voice message through a speaker. Displaying the above normal and abnormal results through an LCD screen, Operation method of noise, vibration, and shock sensors.
5. When a noise, vibration, and shock source is input through a microphone and a MEMS-based 3-axis accelerometer and the running button of an external interface is interrupted, the AI of the noise, vibration, and shock sensor operates to compute and store data of the noise, vibration, and shock source using an ANN algorithm of a storage device; scan the noise, vibration, and shock state of a measurement target through machine learning using the said ANN algorithm, filter and label the data; distinguish normal and abnormal conditions regarding abnormal noise, vibration, and shock through the said machine learning, derive normal and abnormal results to predict an accident, and transmit the normal and abnormal result data to an edge gateway device via wired or wireless communication such as wireless LAN, Bluetooth, or USB; and a noise, vibration, and shock sensor capable of bidirectional communication with said edge gateway device; An edge gateway device that receives normal and abnormal result data of a measurement target from the above noise, vibration, and shock sensor via standardized Ethernet or wireless LAN, filters out duplicate data and abnormal noise data, and transmits the filtered normal and abnormal result data of the measurement target to a cloud server system via standardized Modebus RTU or Modebus TCP; and A cloud server system that stores and monitors result data regarding the normal and abnormal status of a measurement target received from the edge gateway device and the status of abnormalities of the sensor, and remotely controls the measurement target and the noise, vibration, and shock sensor; A noise, vibration, and shock sensor system including
6. A body formed in a rectangular frame shape, having a transmitting/receiving antenna hole, an ON/OFF button hole, a menu selection button hole, or a reset button hole formed on the upper surface, a USB terminal hole formed on one side, and a speaker hole formed on the lower surface; An upper cover positioned on the front of the above body, having a microphone hole and an indicator display window formed on the front; A lower cover disposed on the rear of the above body and having a battery installation groove formed on its upper surface; and A PCB board disposed inside the above body, wherein a transmitting/receiving antenna, an ON/OFF button, a menu selection button or a reset button, a USB terminal, a MEMS-based 3-axis accelerometer, a microphone, a speaker, and an indicator LED display are electrically connected and disposed on the upper part of the board, and a battery is disposed on the lower part of the board; Noise, vibration, and shock sensors including
7. In claim 6, The above noise, vibration, and shock sensor is, An LCD screen is formed on the upper cover, and An LCD screen disposed on the upper part of the PCB substrate and exposed to the outside through the LCD screen window of the upper cover; Noise, vibration, and shock sensors including additional

Description

Sensors with On-Device AI Function Integrated Noise Vibration Impact Sensor for Wired and Wireless Communication Drive, its system, and its operation method The present invention relates to a noise vibration impact sensor with an integrated wired/wireless communication drive and an on-device AI (Artificial Intelligence) function, a system thereof, and a method of operation thereof. More specifically, the invention relates to a noise vibration impact sensor with an integrated wired/wireless communication drive and an on-device AI function that can check the condition of building structures, machinery, and equipment, collect real-time data, and analyze and predict potential risks such as wear, damage, and destruction of an object, a system thereof, and a method of operation thereof. Generally, in the case of architectural structures or mechanical devices, phenomena appearing inside or outside the facility, such as wall cracks caused by external forces, physical vibrations, impacts, and loads, and significant defects can be identified through safety inspections of the facility. Conventional noise, vibration, and shock sensors are provided as standalone sensor components, and measurements are taken using various controller converters and control analyzers from different manufacturers. Additionally, during measurement, vibration acceleration can be verified via an oscilloscope or monitor. Traditionally, in industrial settings, drive motors of machinery and equipment have been the primary sources of vibration, and the causes are mostly identified by analyzing vibration waveforms in conveyor belts, ropes, bearings, circulation pumps, heating and cooling systems, flow control systems, and ventilation systems. Additionally, direct measurements are typically performed by inspectors and managers possessing specialized knowledge or technical expertise. However, conventionally, there is a problem in that it is difficult to analyze and identify the cause based solely on vibration data under the relevant environmental conditions. Furthermore, conventional methods primarily utilize speed to measure vibration or shock levels; however, there is a problem in accurately detecting abnormal vibration conditions as well as defects caused by vibration in machinery, equipment, and buildings when determining and predicting defect conditions of the measurement target. In addition, due to sensors from different manufacturers and various sensor drivers (signal converters, communication transmission devices), issues regarding communication and wired/wireless compatibility, as well as protocol compatibility mismatches, have occurred. In addition, conventional noise, vibration, and shock sensors transmit only raw data converted into electrical signals of the sensor signal, thereby providing an unreasonable environment unsuitable for artificial intelligence processing of small and medium-sized data, which involves re-computing and processing the raw data in the storage of a stored cloud server system to implement AI as big data. In addition, conventional noise, vibration, and shock sensors are standardized into mostly passive sensor products by quantizing analog signals to convert them into digital signals and receiving the converted data to display it on the device itself or to display it on an LCD monitor, electronic display board, instrument panel, etc., which serve as a means of displaying it to a remote terminal device. In addition, there are difficulties in users or safety managers individually inspecting and maintaining the object to measure noise, vibration, and shock conditions in a confined space exposed to risk. FIG. 1 is a block diagram of a noise, vibration, and shock sensor system with an integrated wired/wireless communication drive and on-device AI function according to a first embodiment of the present invention. FIG. 2 is a block diagram of a noise, vibration, and shock sensor system with an integrated wired/wireless communication drive and on-device AI function according to a second embodiment of the present invention. FIGS. 3 to 9 illustrate a noise, vibration, and shock sensor with an integrated wired/wireless communication drive and an on-device AI function according to a first embodiment of the present invention. FIGS. 3 and FIGS. 4 are perspective views, and Fig. 5 is a plan view, and Fig. 6 is a rear view, and Fig. 7 is a side view, and FIGS. 8 to 9 are exploded perspective views. FIGS. 10 to 13 illustrate a noise, vibration, and shock sensor with an integrated wired/wireless communication drive and an on-device AI function according to a second embodiment of the present invention. Fig. 10 is a perspective view, and Fig. 11 is a plan view, and Fig. 12 is a side view, and Fig. 13 is an exploded perspective view. Embodiments of the present invention are described below with reference to the attached drawings so that those skilled in the art can easily implement the invention. However, the present invention may be emb