JPWO2019173381A5 - - Google Patents

Claims (76)

It ’s a system,
The system comprises a monitoring unit positioned within the environment.
An air quality sensor configured to generate particle data about the particles in the environment.
With a temperature sensor configured to generate temperature data,
With a pressure sensor configured to generate pressure data,
With a relative humidity sensor configured to generate humidity data,
A first communication unit including an antenna configured to transmit data directly or indirectly between the monitoring unit and the remote computing unit.
A control device including one or more first processors and one or more first non-temporary memory devices, wherein the one or more first non-temporary memory devices are.
The air quality sensor is made to generate particle data about particles in the environment.
Let the temperature sensor generate temperature data
The pressure sensor is made to generate pressure data,
Have the relative humidity sensor generate humidity data
Using the first communication unit, the temperature data, the pressure data, and the humidity data are transmitted to the remote computing unit.
The first communication unit is used to transmit the particle data generated by the air quality sensor to the remote computing unit.
It has a control device and a control device for storing instructions for controlling the one or more first processors.
The remote computing unit is positioned outside the environment and includes one or more second processors, one or more second communication units, and one or more second non-temporary memory devices. One or more second non-temporary memory devices
Receive and store the particle data
Receives and stores the temperature data, the pressure data, and the humidity data,
Based on the received particle data generated by the air quality sensor, it is determined whether or not the first exposure threshold of the monitoring unit has been exceeded.
The first adjusted particle information is determined based on the received particle data, temperature data, pressure data, and humidity data.
Based on the first adjusted particle information, it is determined whether or not the first exposure threshold is exceeded.
To store instructions for controlling the one or more second processors.
system. The system according to claim 1, wherein the first communication unit and the control device are configured as a single unit. Further, it is provided with a notification mechanism configured to present a notification related to the particle data to a person.
The one or more second non-temporary memory devices of the remote computing unit are the one or more in order for the notification mechanism to present the notification related to the particle data to the person based on the particle data. The system of claim 1 or 2 , which stores additional instructions for controlling the second processor of. The one or more second non-temporary memory devices of the remote computing unit further store environmental data about the environment.
The one or more second non-temporary memory devices of the remote computing unit may be
Access the above environmental data and
The second adjusted particle information is determined based on the received particle data and the environmental data, and the second adjusted particle information is determined.
To determine whether the first exposure threshold has been exceeded based on the second adjusted particle information.
The system according to any one of claims 1 to 3 , wherein further instructions for controlling one or more second processors are stored. The environmental data includes Product Safety Data Sheet (MSDS) data, meteorological data, past detected particle data, data generated by another monitoring unit in the environment, data on activities performed in the environment, and data on activities performed in the environment. And the system of claim 4 , comprising one or more of public data. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate particle data for the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to store instructions for controlling the one or more third processors to transmit the second particle data generated by the air quality sensor to the remote computing unit. Has a second controller
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Stores additional instructions to control the one or more second processors to determine if the first exposure threshold of the second monitoring unit has been exceeded based on the received second particle data. The system according to any one of claims 1 to 5 . The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
The system of claim 6 , wherein further instructions for controlling the one or more second processors are stored. The monitoring unit is a mobile monitoring unit configured to be moved within the environment.
The system according to claim 6 or 7 , wherein the second monitoring unit is a stationary monitoring unit at a fixed position in the environment. The system according to any one of claims 6 to 8 , wherein the monitoring unit and the second monitoring unit are mobile monitoring units configured to be moved in the environment. The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, further instructions are given to control the one or more second processors to determine if the first exposure threshold of the monitoring unit has been exceeded. The system according to any one of claims 6 to 9 , which is stored. The system according to any one of claims 1 to 10 , wherein the first exposure threshold includes a time-weighted average, an acute exposure limit, an upper limit of exposure limit, a lower limit of exposure limit, a flammable limit, and a short-term exposure limit. The monitoring unit further comprises an accelerometer, a gyroscope, and a microphone, and the one or more first non-temporary memory devices.
The accelerometer is made to generate accelerometer data, the gyroscope is made to generate gyroscope data, and the microphone is made to generate sound data.
To transmit the accelerometer data, the gyroscope data, and the sound data to the remote computing unit using the first communication unit.
Stores additional instructions to control the one or more first processors.
The one or more second non-temporary memory devices are to determine an activity performed within a first distance from the monitoring unit based on the accelerometer data, the gyroscope data, and the sound data. The system according to any one of claims 1 to 11 , wherein further instructions for controlling the one or more second processors are stored. The one or more second non-temporary memory devices are such that the wearer of the monitoring unit determines whether to perform an activity based on the accelerometer data, the gyroscope data, and the sound data. 12. The system of claim 12 , wherein further instructions for controlling the one or more second processors are stored. It ’s a monitoring unit,
The monitoring unit is
Cases including entrances and exits,
An air quality sensor that is fluidly connected to the inlet and outlet and configured to generate particle data for particles in the air that are drawn through the inlet.
Accelerometer and
With a gyroscope,
With Mike
With a camera
A communication unit including an antenna configured to transmit data between the monitoring unit and the remote computing unit.
The case comprises one or more processors and a control device which may include one or more non-temporary memory devices, the case surrounding the air quality sensor, the communication unit, and the control device.
The one or more non-temporary memory devices
The air quality sensor is made to generate particle data about particles in the air sucked through the inlet.
Let the accelerometer generate accelerometer data
Let the gyroscope generate gyroscope data,
Let the microphone generate sound data
Let the camera generate imaging data
The communication unit is used to transmit the data generated by the air quality sensor to the remote computing unit.
The communication unit is used to control the one or more processors to transmit the communication unit, the accelerometer data, the gyroscope data, the sound data, and the imaging data to the remote computing unit. A monitoring unit that stores instructions for. The monitoring unit further has a notification mechanism configured to present to a person notifications related to the particle data.
The one or more non-temporary memory devices are for controlling the one or more processors to have the notification mechanism present the notification related to the particle data to the person based on the particle data. 14. The monitoring unit of claim 14 , which stores additional instructions. 15. The monitoring unit of claim 15 , wherein the notification mechanism comprises a display on the case configured to present the notification to the person. The one or more non-temporary memory devices
Receive a remote instruction from the remote computing unit
Further instructions for controlling the one or more processors to have the notification mechanism present the notification related to the particle data to the person based on the remote instruction received from the remote computing unit. The monitoring unit according to claim 15 or 16 , which stores the monitoring unit. The monitoring unit according to any one of claims 15 to 17 , wherein the notification is one or more of alarms, alerts, messages, auditory outputs, electronic communications, electromagnetic communications, visual outputs, and tactile outputs. The monitoring unit further
With a temperature sensor
With a pressure sensor,
The one or more non-temporary memory devices having a relative humidity sensor.
Let the temperature sensor generate temperature data
The pressure sensor is made to generate pressure data,
Have the relative humidity sensor generate humidity data
The communication unit is used to store additional instructions for controlling the one or more processors to transmit the temperature data, the pressure data, and the humidity data to the remote computing unit. Item 12. The monitoring unit according to any one of Items 14 to 18 . The communication unit is further configured to collect location data regarding the location of the monitoring unit in the environment.
The one or more non-temporary memory devices
The communication unit is further configured to collect position data about the position of the monitoring unit in the environment.
The monitoring unit of any one of claims 14-19 , which stores further instructions for controlling the one or more processors to transmit the location data to the remote computing unit. Further, it has a second air quality sensor that is fluidly connected to the inlet and the outlet and is configured to generate second particle data about particles in the air that are sucked through the inlet.
The one or more non-temporary memory devices
The second air quality sensor is made to generate second particle data regarding particles in the air sucked through the inlet.
Based on the particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
One of claims 14-20 , which stores further instructions for controlling the one or more processors to transmit information related to the determination of the first offset to the remote computing unit. The monitoring unit described in. The monitoring unit according to any one of claims 14 to 21 , further comprising a wearable function configured to allow the monitoring unit to be worn by the person within the breathing zone of the person. It is a method for monitoring the state of the environment, and the above method is
At the stage of using an air quality sensor to generate particle data about particles in the environment on a monitoring unit positioned in the environment,
The stage of transmitting the particle data from the monitoring unit to the remote computing unit outside the environment, and
Based on the particle data generated by the air quality sensor, a step of determining whether or not the first threshold value has been exceeded, and
Using the accelerometer, gyroscope, and microphone on the monitoring unit to generate accelerometer data, gyroscope data, and sound data, respectively.
The stage of transmitting the accelerometer data, the gyroscope data, and the sound data from the monitoring unit to the remote computing unit, and
Based on the accelerometer data, the gyroscope data, and the sound data, a step of determining whether or not the activity is performed within the first distance of the monitoring unit.
How to prepare. 23. The method of claim 23 , wherein the transmitting step is performed at the same time as the generating step. 23. The method of claim 23 or 24 , wherein the determination step is performed at least partially on the remote computing unit. Further, a step of generating temperature data, pressure data, and humidity data using the temperature sensor, pressure sensor, and relative humidity sensor on the monitoring unit, respectively.
The stage of transmitting the temperature data, the pressure data, and the humidity data from the monitoring unit to the remote computing unit, and
A step of determining adjusted particle information based on the particle data, the temperature data, the pressure data, and the humidity data.
The method according to any one of claims 23 to 25 , comprising a step of determining whether or not the first threshold value has been exceeded based on the adjusted particle information. One of claims 23 to 26 further comprising a step of determining whether or not the activity is being performed by the wearer of the monitoring unit based on the accelerometer data, the gyroscope data, and the sound data. The method described in the section . A step of generating imaging data using a camera on the surveillance unit based on one or more of the accelerometer data, the gyroscope data, and the sound data.
The method according to any one of claims 23 to 27 , further comprising a step of transmitting the imaging data from the monitoring unit to the remote computing unit. It ’s a system,
A monitoring unit positioned within the environment
An air quality sensor configured to generate particle data about the particles in the environment.
A first communication unit having an antenna configured to transmit data directly or indirectly between the monitoring unit and the remote computing unit.
The air quality sensor is made to generate particle data about one or more first processors and particles in the environment, and the first communication unit is used to generate the particle data generated by the air quality sensor. A control device comprising one or more first non-temporary memory devices for storing instructions for controlling the one or more first processors to be transmitted to the remote computing unit.
With a monitoring unit that has
The remote computing unit, positioned outside the environment, stores one or more second processors, one or more second communication units, and environmental data about the environment.
Access the above environmental data and
The second adjusted particle information is determined based on the received particle data and the environmental data, and the second adjusted particle information is determined.
The particle data is received and stored,
Based on the particle data generated and received by the air quality sensor, it is determined whether the monitoring unit has exceeded the first exposure threshold.
Whether or not the first exposure threshold is exceeded is determined based on the second adjusted particle information.
With the remote computing unit comprising one or more second non-temporary memory devices for storing instructions for controlling the one or more second processors.
A system equipped with. 29. The system of claim 29, wherein the first communication unit and the control device are configured as a single unit. Further, it is provided with a notification mechanism configured to present a notification related to the particle data to a person.
The one or more second non-temporary memory devices of the remote computing unit are used to cause the notification mechanism to present the notification related to the particle data to the person based on the particle data.
29 or 30. The system of claim 29 or 30, which stores additional instructions for controlling the one or more second processors. The environmental data includes Product Safety Data Sheet (MSDS) data, meteorological data, past detected particle data, data generated by another monitoring unit in the environment, data on activities performed in the environment, and data on activities performed in the environment. 30 and the system of claim 30, comprising one or more of public data. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate particle data for the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
With a second control device that stores instructions for controlling the one or more third processors.
Have,
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Based on the received second particle data, determine whether the first exposure threshold of the second monitoring unit has been exceeded.
31. The system of claim 31, which stores additional instructions for controlling the one or more second processors. The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
33. The system of claim 33, which stores additional instructions for controlling the one or more second processors. The monitoring unit is a mobile monitoring unit configured to be moved within the environment.
The system according to claim 33 or 34, wherein the second monitoring unit is a stationary monitoring unit at a fixed position in the environment. The system according to any one of claims 33 to 35, wherein the monitoring unit and the second monitoring unit are mobile monitoring units configured to be moved in the environment. The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, determine whether the first exposure threshold of the monitoring unit has been exceeded.
The system according to any one of claims 33 to 36, wherein further instructions for controlling the one or more second processors are stored. 31. The system of claim 31, wherein the first exposure threshold includes a time-weighted average, an acute exposure limit, an upper limit of the exposure limit, a lower limit of the exposure limit, a flammable limit, and a short-term exposure limit. The monitoring unit further comprises an accelerometer, a gyroscope, and a microphone, and the one or more first non-temporary memory devices.
The accelerometer is made to generate accelerometer data, the gyroscope is made to generate gyroscope data, and the microphone is made to generate sound data.
To transmit the accelerometer data, the gyroscope data, and the sound data to the remote computing unit using the first communication unit.
Stores additional instructions to control the one or more first processors.
The one or more second non-temporary memory devices are to determine an activity performed within a first distance from the monitoring unit based on the accelerometer data, the gyroscope data, and the sound data. 31. The system of claim 31, which stores additional instructions for controlling the one or more second processors. The one or more second non-temporary memory devices are such that the wearer of the monitoring unit determines whether to perform an activity based on the accelerometer data, the gyroscope data, and the sound data. 39. The system of claim 39, wherein further instructions for controlling the one or more second processors are stored. It ’s a system,
A monitoring unit positioned within the environment
An air quality sensor configured to generate particle data about the particles in the environment.
With a first communication unit having an antenna configured to transmit data directly or indirectly between the monitoring unit and the remote computing unit and between the monitoring unit and the second monitoring unit. ,
The air quality sensor is made to generate particle data about the particles in the environment.
The first communication unit is used to transmit the particle data generated by the air quality sensor to the remote computing unit.
A control device comprising one or more first non-temporary memory devices and one or more first processors that store instructions for controlling the one or more first processors.
With a monitoring unit that has
The second monitoring unit positioned in the environment.
A second air quality sensor configured to generate data about the particles in the environment.
A third communication unit having an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second particle data for the particles in the environment is generated by the second air quality sensor.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
A second control device comprising one or more third non-temporary memory devices and one or more third processors that store instructions for controlling the one or more third processors.
With the second monitoring unit having
The remote computing unit, positioned outside the environment, with one or more second processors and one or more second communication units.
The particle data is received and stored,
The second particle data is received and stored, and
Based on the particle data generated and received by the air quality sensor, it is determined whether the monitoring unit has exceeded the first exposure threshold.
Based on the received second particle data, it is determined whether or not the first exposure threshold has been exceeded for the second monitoring unit.
With the remote computing unit comprising one or more second non-temporary memory devices for storing instructions for controlling the one or more second processors.
A system equipped with. The system according to claim 41, wherein the first communication unit and the control device are configured as a single unit. Further, it is provided with a notification mechanism configured to present a notification related to the particle data to a person.
The one or more second non-temporary memory devices of the remote computing unit are used to cause the notification mechanism to present the notification related to the particle data to the person based on the particle data.
41. The system of claim 41 or 42, which stores additional instructions for controlling the one or more second processors. The one or more second non-temporary memory devices of the remote computing unit further store environmental data about the environment.
The one or more second non-temporary memory devices of the remote computing unit may be
Access the above environmental data and
The second adjusted particle information is determined based on the received particle data and the environmental data.
Based on the second adjusted particle information, it is determined whether or not the first exposure threshold is exceeded.
As such, it stores additional instructions for controlling the one or more second processors.
The environmental data includes Material Safety Data Sheet (MSDS) data, meteorological data, past detected particle data, data generated by another monitoring unit in the environment, and data about activities performed in the environment. , And one or more of the public data,
The system according to any one of claims 41 to 43. The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
The system according to any one of claims 41 to 44, wherein further instructions for controlling the one or more second processors are stored. The monitoring unit is a mobile monitoring unit configured to be moved within the environment.
The system according to any one of claims 41 to 45, wherein the second monitoring unit is a stationary monitoring unit at a fixed position in the environment. The system according to any one of claims 41 to 46, wherein the monitoring unit and the second monitoring unit are mobile monitoring units configured to be moved in the environment. The one or more second non-temporary memory devices of the remote computing unit may be
Based on the received particle data and the second particle data, determine whether the first exposure threshold of the monitoring unit has been exceeded.
The system according to any one of claims 42 to 47, wherein further instructions for controlling the one or more second processors are stored. The system of any one of claims 42-48, wherein the first exposure threshold includes a time-weighted average, an acute exposure limit, an upper limit of the exposure limit, a lower limit of the exposure limit, a flammable limit, and a short-term exposure limit. The monitoring unit further comprises an accelerometer, a gyroscope, and a microphone, and the one or more first non-temporary memory devices.
The accelerometer is made to generate accelerometer data, the gyroscope is made to generate gyroscope data, and the microphone is made to generate sound data.
To transmit the accelerometer data, the gyroscope data, and the sound data to the remote computing unit using the first communication unit.
Stores additional instructions to control the one or more first processors.
The one or more second non-temporary memory devices are to determine an activity performed within a first distance from the monitoring unit based on the accelerometer data, the gyroscope data, and the sound data. The system of any one of claims 42-49, comprising further instructions for controlling the one or more second processors. The one or more second non-temporary memory devices are such that the wearer of the monitoring unit determines whether to perform an activity based on the accelerometer data, the gyroscope data, and the sound data. 50. The system of claim 50, wherein further instructions for controlling the one or more second processors are stored. It ’s a system,
A monitoring unit positioned within the environment
An air quality sensor configured to generate particle data about the particles in the environment.
Accelerometer and
With a gyroscope,
Microphone,
A first communication unit having an antenna configured to transmit data directly or indirectly between the monitoring unit and the remote computing unit.
One or more first processors, and
The air quality sensor is made to generate particle data about particles in the environment.
Let the accelerometer generate accelerometer data
Let the gyroscope generate gyroscope data,
Let the microphone generate sound data
The first communication unit is used to transmit the particle data generated by the air quality sensor to the remote computing unit.
The first communication unit is used to transmit the accelerometer data, the gyroscope data, and the sound data to the remote computing unit.
With a control device including one or more first non-temporary memory devices for storing instructions for controlling the one or more first processors.
With a monitoring unit that has
The remote computing unit, positioned outside the environment, with one or more second processors and one or more second communication units.
The particle data is received and stored,
Based on the particle data generated and received by the air quality sensor, it is determined whether the monitoring unit has exceeded the first exposure threshold.
Based on the accelerometer data, the gyroscope data, and the sound data, the activity performed within the first distance from the monitoring unit is determined.
With the remote computing unit comprising one or more second non-temporary memory devices for storing instructions for controlling the one or more second processors.
A system equipped with. 52. The system of claim 52, wherein the first communication unit and the control device are configured as a single unit. Further, it is provided with a notification mechanism configured to present a notification related to the particle data to a person.
The one or more second non-temporary memory devices of the remote computing unit are used to cause the notification mechanism to present the notification related to the particle data to the person based on the particle data.
52 or 53. The system of claim 52 or 53, which stores additional instructions for controlling the one or more second processors. The one or more second non-temporary memory devices of the remote computing unit further store environmental data about the environment.
The one or more second non-temporary memory devices of the remote computing unit may be
Access the above environmental data and
The second adjusted particle information is determined based on the received particle data and the environmental data.
Based on the second adjusted particle information, it is determined whether or not the first exposure threshold is exceeded.
As such, it stores additional instructions for controlling the one or more second processors.
The environmental data includes Material Safety Data Sheet (MSDS) data, meteorological data, past detected particle data, data generated by another monitoring unit in the environment, and data about activities performed in the environment. , And one or more of the public data,
The system according to any one of claims 52 to 54. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate data about the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including the one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
With a second control device that stores instructions for controlling the one or more third processors.
Have,
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Based on the received second particle data, it is determined whether or not the first exposure threshold of the second monitoring unit has been exceeded.
Based on the received particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
The system according to any one of claims 52 to 55, wherein further instructions for controlling the one or more second processors are stored. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate particle data for the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
With a second control device that stores instructions for controlling the one or more third processors.
Have,
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Based on the received second particle data, determine whether the first exposure threshold of the second monitoring unit has been exceeded.
Stores additional instructions to control the one or more second processors.
The monitoring unit is a mobile monitoring unit configured to move in the environment.
The second monitoring unit is a stationary monitoring unit at a fixed position in the environment.
The system according to any one of claims 52 to 56. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate particle data for the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
With a second control device that stores instructions for controlling the one or more third processors.
Have,
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Based on the received second particle data, determine whether the first exposure threshold of the second monitoring unit has been exceeded.
Stores additional instructions to control the one or more second processors.
The monitoring unit and the second monitoring unit are mobile monitoring units configured to move in the environment.
The system according to any one of claims 52 to 57. The system further comprises a second monitoring unit positioned within the environment.
A second air quality sensor configured to generate data about the particles in the environment.
A third communication unit including an antenna configured to transmit data between the second monitoring unit and the remote computing unit.
The second control device including one or more third processors and the one or more third non-temporary memory devices, wherein the one or more third non-temporary memory devices are.
The second air quality sensor is made to generate the second particle data regarding the particles in the environment.
The third communication unit is used to transmit the second particle data generated by the air quality sensor to the remote computing unit.
With a second control device that stores instructions for controlling the one or more third processors.
Have,
The first communication unit is further configured to transmit data between the second monitoring units.
The one or more second non-temporary memory devices of the remote computing unit may be
Receives and stores the second particle data,
Based on the received second particle data, it is determined whether or not the first exposure threshold of the second monitoring unit has been exceeded.
Based on the received particle data and the second particle data, it is determined whether or not the monitoring unit has exceeded the first exposure threshold.
The system according to any one of claims 52 to 58, wherein further instructions for controlling the one or more second processors are stored. The system according to any one of claims 52 to 59, wherein the first exposure threshold includes a time-weighted average, an acute exposure limit, an upper limit of exposure limit, a lower limit of exposure limit, a flammable limit, and a short-term exposure limit. The one or more second non-temporary memory devices are such that the wearer of the monitoring unit determines whether to perform an activity based on the accelerometer data, the gyroscope data, and the sound data. The system according to any one of claims 52 to 60, wherein further instructions for controlling the one or more second processors are stored. It ’s a monitoring unit,
Cases with entrances and exits,
An air quality sensor configured to generate particle data about particles in the air that are fluid-connected to the inlet and outlet and sucked through the inlet.
A second air quality sensor fluid connected to the inlet and outlet and configured to generate second particle data for particles in the air sucked through the inlet.
A communication unit having an antenna configured to transmit data between the monitoring unit and the remote computing unit.
With a controller including one or more processors and one or more non-temporary memory devices
Equipped with
The case surrounds the air quality sensor, the communication unit, and the control device.
The one or more non-temporary memory devices
The air quality sensor is made to generate particle data about particles in the air sucked through the inlet.
The second air quality sensor is made to generate second particle data about particles in the air sucked through the inlet.
Based on the particle data and the second particle data, it is determined whether or not the particle data deviates from the second particle data by the first offset.
The communication unit is used to transmit the data generated by the air quality sensor to the remote computing unit.
Information related to the determination of the first offset is transmitted to the remote computing unit.
Store instructions for controlling the one or more processors, as described above.
Monitoring unit. The monitoring unit further has a notification mechanism configured to present to a person notifications related to the particle data.
The one or more non-temporary memory devices are for controlling the one or more processors in order for the notification mechanism to present the notification related to the particle data to the person based on the particle data. 62. The monitoring unit of claim 62, which stores additional instructions. The monitoring unit of claim 63, wherein the notification mechanism comprises a display on the case configured to present the notification to the person. The one or more non-temporary memory devices
Receive a remote instruction from the remote computing unit
To have the notification mechanism present the notification related to the particle data to the person based on the remote instruction received from the remote computing unit.
The monitoring unit according to claim 63 or 64, which stores additional instructions for controlling the one or more processors. The monitoring unit according to any one of claims 63 to 65, wherein the notification is one or more of alarms, alerts, messages, auditory outputs, electronic communications, electromagnetic communications, visual outputs, and tactile outputs. The monitoring unit further
With a temperature sensor
With a pressure sensor,
The one or more non-temporary memory devices having a relative humidity sensor.
Let the temperature sensor generate temperature data
The pressure sensor is made to generate pressure data,
Have the relative humidity sensor generate humidity data
The communication unit is used to transmit the temperature data, the pressure data, and the humidity data to the remote computing unit.
The monitoring unit according to any one of claims 62 to 66, which stores further instructions for controlling the one or more processors. The communication unit is further configured to collect location data regarding the location of the monitoring unit in the environment.
The one or more non-temporary memory devices
The communication unit is further configured to collect position data about the position of the monitoring unit in the environment.
To transmit the location data to the remote computing unit
The monitoring unit according to any one of claims 62 to 67, which stores further instructions for controlling the one or more processors. The monitoring unit according to any one of claims 62 to 68, further comprising a wearable function configured to allow the monitoring unit to be worn by the person within the breathing zone of the person. It ’s a monitoring unit,
Cases with entrances and exits,
An air quality sensor configured to generate particle data about particles in the air that are fluid-connected to the inlet and outlet and sucked through the inlet.
With wearable features configured to allow the surveillance unit to be worn by a person within a person's breathing zone,
A communication unit having an antenna configured to transmit data between the monitoring unit and the remote computing unit.
With a controller including one or more processors and one or more non-temporary memory devices
Equipped with
The case surrounds the air quality sensor, the communication unit and the control device.
The one or more non-temporary memory devices
The air quality sensor is made to generate particle data about particles in the air sucked through the inlet.
The communication unit is used to transmit the data generated by the air quality sensor to the remote computing unit.
Store instructions for controlling the one or more processors, as described above.
Monitoring unit. The monitoring unit further has a notification mechanism configured to present to a person notifications related to the particle data.
The one or more non-temporary memory devices are for controlling the one or more processors to have the notification mechanism present the notification related to the particle data to the person based on the particle data. The monitoring unit of claim 70, which stores additional instructions. 11. The monitoring unit of claim 71, wherein the notification mechanism comprises a display on the case configured to present the notification to the person. The one or more non-temporary memory devices
Receive a remote instruction from the remote computing unit
To have the notification mechanism present the notification related to the particle data to the person based on the remote instruction received from the remote computing unit.
The monitoring unit according to claim 71 or 72, which stores additional instructions for controlling the one or more processors. The monitoring unit according to any one of claims 71 to 73, wherein the notification is one or more of alarms, alerts, messages, auditory outputs, electronic communications, electromagnetic communications, visual outputs, and tactile outputs. The monitoring unit further
With a temperature sensor
With a pressure sensor,
The one or more non-temporary memory devices having a relative humidity sensor.
Let the temperature sensor generate temperature data
The pressure sensor is made to generate pressure data,
Have the relative humidity sensor generate humidity data
The communication unit is used to transmit the temperature data, the pressure data, and the humidity data to the remote computing unit.
The monitoring unit according to any one of claims 70 to 74, which stores further instructions for controlling the one or more processors. The communication unit is further configured to collect location data regarding the location of the monitoring unit in the environment.
The one or more non-temporary memory devices
The communication unit is further configured to collect position data about the position of the monitoring unit in the environment.
To transmit the location data to the remote computing unit
The monitoring unit according to any one of claims 70 to 75, which stores further instructions for controlling the one or more processors.