TW201413667A - Ambient detection system and portable ambient measurement device thereof - Google Patents

Abstract

The present invention relates to a controlled device and an ambient detection system. The ambient detection system includes a portable ambient measurement device and a remote server. The portable ambient measurement device could insert at least one of a plurality of plug-in measurement modules. End user can measure the different ambient parameters by replacing different plug-in measurement modules, such as radiation, luminance, electromagnetic, temperature, humidity and the concentration of poison gas. Further, the portable ambient measurement device has a wireless internet transmission module for transmitting the measurement data to the remote server. In addition, the remote server is used for recording the abovementioned ambient parameters. The end user can realize the variation of the ambient, such as increasing of the concentration of poison gas, such that the immediate danger might be prevented. Moreover, the user can use the internet to log-in the remote server and monitor the variations of the ambient parameters through a software interface.

Description

Environmental monitoring system and its portable environment measurement

The present invention relates to an environmental measuring device, and more particularly to an environmental monitoring system that can perform remote operations and a portable environmental measuring device therefor.

There are many kinds of temperature and humidity monitoring products on the market, and they are widely used in museums, libraries, hospitals, clean rooms, food factories, etc. Arenstein lists the characteristics of temperature and humidity recorders commonly used in 13 museums to provide an application development environment. Reference to the monitoring system (Arenstein, 2002).

In addition to temperature and humidity monitoring, many studies have attempted to use data transmission technology to establish a variety of remote environmental monitoring system architectures that facilitate managers to instantly grasp and monitor environmental conditions. Lim and Ryoo have established a remote ambient temperature monitoring system for food refrigeration. The sensor is connected to the central computer via the RS-485 interface. The administrator can monitor the refrigerators by using a specific software interface on the central computer. The temperature status ensures immediate processing in the event of problems in individual refrigerators (Lim & Ryoo, 2004).

Among the commercial products, Rotronic has produced a series of temperature and humidity handheld recorders and transmitters suitable for museums, hospitals, and clean rooms. It can be transmitted to a computer via a wired RS-232 interface to store and record several monitoring points. Conditions (http://www.rotronic.com/). The wireless environment monitoring system "Microlog Plus" produced by Fourier Systems replaces the wired data transmission from the sensor to the central control computer segment by radio technology. It is within the receiving range of 300 meters outside and 75 meters indoors. The control computer can monitor the environmental status of up to 200 monitoring points (http://www.fourier-sys.com/).

Each of the above systems is based on a centrally controlled computer-centric architecture. The monitoring points are transmitted to the central control computer by wired or wireless technology within a certain range. The architecture system is limited by wired or wireless transmission technology. The monitoring radius is within a few hundred meters and cannot be used for large-scale monitoring of floors or different buildings. In addition, the above several systems all belong to several environmental parameters of fixed monitoring. If it is necessary to change the types of monitoring environment parameters, other testing equipments need to be set up. Therefore, the user cannot flexibly use the original system for monitoring.

In recent years, radiation problems have received increasing attention. The incidents of nuclear power plants in Japan have caused global people to be highly panicked about nuclear energy, and there have been many oppositions to nuclear energy acquisition in China. At present, Taiwan's main power generation is mostly based on coal products, oil and natural gas. The power output cost is not only increasing with the shortage of materials, but also the pollution of carbon dioxide emitted during the output process is not in line with the environmental consensus that the world is promoting. In contrast, the unit cost of nuclear energy is much lower than other types of power generation, and there is no shortage of resources. The power generation process of nuclear energy has almost no problems such as carbon dioxide emissions, and it is a high-efficiency, low-pollution power generation type. When the high cost of power generation is gradually reflected in electricity bills and people's livelihood supplies, perhaps the society will once again consider accepting nuclear power generation. At that time, all kinds of imported radioactive mineral materials need to be properly resettled and monitored, and the public also needs to strengthen radiation concepts and preventive measures.

Common wireless transmission technology is difficult to achieve regional operation. If the detection object such as radiation has high distance and high destructive power, the distance that common wireless transmission technology can provide cannot effectively protect the measurer from negative environmental factors. This study explores the above, develops and produces environmental exploration and measurement tools that can replace manual measurements.

The invention provides an environmental monitoring system for achieving the function of remotely monitoring environmental parameters.

The invention provides a portable environment measuring device, which has a built-in wireless network module, which can detect environmental parameters through a remote transmission mode and transmit environmental parameters to a remote server.

The present invention provides a portable environment measuring device for transmitting measured environmental parameters to a remote server. The portable environment measuring device includes at least one slot, a control circuit and a wireless network. Road transmission module. The at least one slot is configured to insert at least one of the plurality of removable measurement modules, wherein each of the removable measurement modules is configured to measure different environments parameter. The control circuit is coupled to the at least one slot for receiving the environmental parameter measured by the replaceable measurement module in the at least one slot. The wireless network transmission module is coupled to the control circuit, and receives the environmental parameters measured by the removable measurement module, and outputs the measured environmental parameters to the remote server through a network interface, where The remote server is configured to record the measured environmental parameter and the amount of change thereof. When the measured amount of the environmental parameter exceeds a predetermined value, the remote server starts a warning function.

The invention further provides an environmental monitoring system comprising a remote server and a portable environment measuring device. The portable environment measuring device comprises at least one slot, a control circuit and a wireless network transmission module. The at least one slot is configured to insert at least one of the plurality of removable measurement modules, wherein each of the removable measurement modules is configured to measure different environments parameter. The control circuit is coupled to the at least one slot for receiving the replaceable amount in the at least one slot Measure the environmental parameters measured by the module. The wireless network transmission module is coupled to the control circuit, and receives the environmental parameters measured by the removable measurement module, and outputs the measured environmental parameters to the remote server through a network interface, where The remote server is configured to record the measured environmental parameter and the amount of change thereof. When the measured amount of the environmental parameter exceeds a predetermined value, the remote server starts a warning function.

According to the environment monitoring system and the portable environment measuring device according to the preferred embodiment of the present invention, the portable environment measuring device includes a global positioning system coupled to the control circuit for performing a positioning to obtain a portable A location information of the environmental measurement device, wherein the control circuit transmits the location information to the remote server through the wireless network transmission module.

According to the environmental monitoring system and the portable environment measuring device according to the preferred embodiment of the present invention, the portable environment measuring device includes a mobile module coupled to the control circuit for carrying the portable environment measuring device. The user operates the remote server and controls the mobile module through the network interface to move the environmental monitoring system.

According to the environment monitoring system and the portable environment measuring device according to the preferred embodiment of the present invention, the portable environment measuring device includes an image capturing module coupled to the control circuit for performing image capturing. The control circuit transmits the image captured by the image capturing module to the remote server through the wireless network transmission module.

According to the environmental monitoring system and the portable environment measuring device according to the preferred embodiment of the present invention, the removable measuring module includes at least one of the following: a radiation intensity measuring module and a light measuring module. , an electromagnetic strength measuring module, a temperature measuring module, a humidity measuring module, a toxic gas concentration measuring module, a smoke measuring module and a fire warning module .

The spirit of the present invention is mainly to design an environmental monitoring system, which is composed of a portable environment measuring device and a remote server. The portable environment measuring device can be inserted into at least one of the plurality of removable measuring modules. The user can measure different environmental parameters by replacing the above-mentioned replaceable measurement module. For example, radiation intensity, luminosity, electromagnetic strength, temperature, humidity, and toxic gas concentration, and the like. Moreover, the portable environment measuring device is configured with a wireless network transmission module, and can output a plurality of measured environmental parameters to the remote server through a network interface. In addition, the remote server is used to record the above environmental parameters to understand environmental changes, such as whether the concentration of toxic gases continues to increase to prevent dangers from occurring in advance. In addition, the user can log in to the remote server through the network and monitor the change of the environmental parameters through a software interface.

In addition, in order to respond to a crisis, personnel cannot enter the inspection site of the dangerous area. The portable environmental measuring device is provided with a camera and a mobile module, and the mobile module can be driven by a tire or a flight module. The user can log in to the remote server to remotely control the portable environment measuring device to enter the environmental parameters of the inspected site in the dangerous area. For example, if the radioactive material leaks, the user can control the portable environmental measuring device to enter the radioactive substance leakage area to measure the radiation intensity to confirm whether the person can enter the treatment.

The detailed description of the present invention and the accompanying drawings are to be understood by the claims The scope is subject to any restrictions.

In the following, the invention will be described in detail by the embodiments of the invention, and the same reference numerals are used in the drawings.

First embodiment

1 is a circuit block diagram of an environmental monitoring system according to a first embodiment of the present invention. Referring to FIG. 1, the environmental monitoring system includes a remote server 101 and a portable environment measuring device 102. The portable environment measuring device comprises a slot 1021, a control circuit 1022 and a wireless network transmission module 1023. Although this embodiment has only one slot 1021, it will be appreciated by those of ordinary skill in the art that in system design, the number of slots 1021 can be flexibly varied depending on the design. The details are not described below.

The slot 1021 is configured to insert at least one of the plurality of removable measurement modules. The removable measurement module can be, for example, a radiation intensity measurement module, a light measurement module, an electromagnetic strength measurement module, a temperature measurement module, a humidity measurement module, and a toxic gas concentration. Measuring module, a smoke measuring module and a fire warning module.

The control circuit 1022 is coupled to the slot 1021 for receiving the environmental parameter measured by the removable measurement module in the slot 1021. The wireless network transmission module 1023 is coupled to the control circuit for outputting the measured environmental parameters to the remote server 101 through a network interface, such as 802.11b/g or Bluetooth. The remote server 101 is configured to record the measured environmental parameters and the amount of change thereof. When the amount of change of the measured environmental parameters exceeds a predetermined value, the remote server 101 activates an alert function.

It can be seen from the above-mentioned first embodiment that the present embodiment can be placed at a position to be monitored at any time by utilizing the convenience of the portable environment measuring device. There is no need to fix, and the portable environmental measuring device has the function of being able to exchange its corresponding measuring module. Therefore, the environmental monitoring system is full of flexibility in application. The user can arbitrarily change its monitoring position and the environmental parameters it wants to monitor.

Second embodiment

2 is a circuit block diagram of a portable environment measuring device according to a second embodiment of the present invention. Referring to FIG. 2, in the second embodiment, the portable environment measuring device includes a global positioning system module 204 in addition to the original slot 201, the control circuit 202, and the wireless network transmission module 203. a mobile module 205 and an image capture module 206. The global positioning system module 204 is coupled to the control circuit 202 for performing a GPS positioning to obtain a position information of the portable environmental measuring device. The mobile module 205 is coupled to the control circuit 202 for carrying and moving the portable environment measuring device. The image capture module 206 is coupled to the control circuit 202 for performing image capture.

3 is a schematic diagram of a remote server according to a second embodiment of the present invention. Referring to FIG. 3, in this embodiment, the remote server 101 can be, for example, a tablet computer. Referring to FIG. 2 and FIG. 3 simultaneously, in the second embodiment, the user can log in to the tablet computer of FIG. 3 to control the portable environment measuring device. In FIG. 3, the tablet has a soft interface on the upper side, and the right block 301 has a virtual control touch button that is up, down, left, and right and paused. The middle picture block 302 is the location information captured by the global positioning system module 204 that can carry the environmental measurement device, and matches the current position displayed on the map. The left block 303 is captured by the image capturing module 206 of the portable environment measuring device to the currently photographed location. The upper block 304 is a message block for displaying the currently detected Environmental parameters. In this second embodiment, there are radiation intensity, fire warning, temperature, humidity, luminosity, and toxic gas concentration from left to right. Although only the above-mentioned several types are shown in the figure, those skilled in the art should know that the above is merely an example, and the designer may change the design or increase the design parameters according to the application, and thus the present invention does not limit the above-mentioned several environmental parameter detections. .

In this embodiment, the global positioning system module 204, the mobile module 205, and the image capturing module 206 are all coupled to the control circuit 202 and controlled by the control circuit 202. In the preferred embodiment, the above modules are all detachable, so that they can be properly configured according to the application. For example, when the portable environment measuring device is disposed in the vehicle, the portable environment measuring device can only configure the global positioning system module 204 and the image capturing module 206, so that, in addition to being used as navigation, It can also be used as a driving recorder. In addition, the additional slot 201 can also be configured with, for example, smoke detection, fire detection, and toxic gas detection. Thus, assuming that the driver burns carbon on the vehicle or commits suicide by exhausting the exhaust gas, it can be immediately transmitted to the remote server 101 through the network, and the remote server 101 activates its built-in warning function, and the remote servo The user of the device 101 can know the location of the person driving the car and the car, and immediately inform the police to avoid the regret.

Furthermore, when a disaster occurs, when a person cannot enter, such as a nuclear accident, the portable environment measuring device can configure the mobile module 205 and the image capturing module 206, and the other slot 201 can be inserted, for example, by the amount of radiation intensity. The test module can remotely remotely control the portable environmental measuring device through the remote server 101, and enter the nuclear disaster zone to measure the radiation intensity to determine the situation.

In addition, the above embodiments of the present invention are equally applicable to, for example, a museum The hospital, the clean room, and the like, and because of the plug-in design of the invention, the removable measuring module can be replaced according to different needs at any time, and therefore, the use is more flexible.

Experimental result

In the following, the applicant uses the spirit of the present invention to actually create a prototype machine to implement an environmental exploration and measurement tool for how to use the remote control technology to effectively protect the measurer and prevent negative environmental factors from causing persecution to the human body. . In the detection of a regional environment, various types of negative environmental factors, such as radiation or gas, are often hidden, which is a common concern for traditional manual detection of security. In this experiment, the tools were built to integrate mobile smart systems, 3G wireless networks, WIFI wireless transmission, radiation sensing circuits, and wireless IP cameras. Designed with the concept of a remote control car and actually produced. This tool is ideal for cross-regional control, providing unmanned tools for comprehensive environmental exploration and measurement.

Figure 4 is a system architecture diagram of the prototype of this experiment. According to FIG. 4, when the user 401 operates the interface program written on the smart system end 402, the program instructions are transmitted to the network server (Web Server) 403 via the wireless transmission circuit, and the microprocessor (MCU) The 404 will immediately grab the network server 403 source command and trigger the motor control circuit to move the remote control car 405 in the direction specified by the user. The environmental factor detection circuit 406 located in the remote control car 405 transmits its sensed changes back to the microprocessor 404. The conversion frequency and the analog digital converter (ADC) are used to convert the pulse frequency or the sensing voltage of each sensor into a digital value, and finally the data is transmitted back to the network server 403 through wireless transmission, and the value is finally passed through the smart type. The system 402 captures the display in the interface program. Placed in remote control car during the process The IP camera 407 in the 405 will synchronously return the image of the view to the interface program through the web server 403 for the user to perform remote control exploration.

Figure 5 is a schematic diagram of the wireless transmission setting of the experiment. As shown in FIG. 5, the microprocessor (MCU) 501 and the wireless transmission module 502 first perform initialization setup using a Universal Asynchronous Receiver/Transmitter (hereinafter commonly referred to as UART) transmission, and the wireless transmission module 502. By connecting to the wireless router 503 and then exchanging data with the Web server 504 by the wireless router 503, the system architecture for remote transmission can be achieved.

Next, Figure 6 is a firmware flow chart of the experiment. Referring to FIG. 6, the timer, the external interrupt counter, the stop motor movement rotation are kept in a static state, to avoid system damage, and the Geiger hardware circuit is started, and the system will delay for several seconds until the circuit reaches a steady state. The preset Geiger counting time is 60 seconds, and the voltage pulse signal generated by the Geiger counter is measured, and the pulse counting is started by the external interrupt counter of the microprocessor (MCU), and the time and the pulse number are synchronously transmitted by wireless transmission. To the device specified by the user. If the Geiger count time is zero, the measurement procedure is re-executed until the end of the process.

When the wireless transmission module successfully receives the data from the network server moving direction, it determines whether the moving state changes, and if the moving state changes, immediately changes the state of the motor moving. The steps in Figure 6 are detailed below:

Step S601: Start.

Step S602: Initialize the system.

Step S603: Start the Geiger hardware circuit.

Step S604: Wait for ten seconds to stabilize the Geiger hardware circuit.

Step S605: Start timing for sixty seconds.

Step S606: Geiger pulse counting.

Step S607: WIFI transmits Geiger data.

Step S608: It is judged whether or not sixty seconds have been counted. When the count expires, step S609 is performed.

Step S609: determining whether to stop the measurement. When it is judged that the measurement is stopped, the process proceeds to step S613, and if not, the process proceeds to step S606.

Step S610: The WIFI receives the moving direction data.

Step S611: It is judged whether or not the moving direction is changed. When it is judged that the remote control car needs to change direction, step S612 is performed. Otherwise, step S610 is performed.

Step S612: Change the moving direction.

Step S613: End detecting the amount of ambient radiation.

Step S614: Start the environment detection circuit. Here, the environment detecting circuit can include, for example, detecting temperature, humidity, luminosity, toxic gas concentration, and the like.

Step S615: Perform environment detection, and convert the analog signal detected by the sensor into digital environment detection data.

Step S616: Using WIFI to transmit digital environment detection data.

Step S617: It is judged whether to stop the measurement. When it is judged that the measurement is stopped, step S618 is performed, otherwise, step S615 is continued.

Step S618: Ending the environment detection.

Figure 7 is a software flow diagram of the experiment. As shown in Figure 7, when the video stream address of the network camera is successfully connected, and the smart system device is used for receiving and playing the video stream, the dynamic instant image can be viewed, and the security between the lines is greatly increased.

When the wireless transmission is successfully connected to the Web server (Web Server), the counting time and the Geiger voltage pulse data can be obtained. The intelligent system device is used to perform the program algorithm, and the voltage pulse frequency is calculated as the relative radiation amount by using the mathematical formula. (The unit is Wei Xifu). The counting time will be displayed on the program interface. If the radiation sensing circuit detects a safe value exceeding the predetermined radiation, an alarm will be generated immediately to remind the user to achieve warning and prevention effects. The steps in Figure 7 are detailed below:

Step S701: Start.

Step S702: Initializing the system

Step S703: Connecting a network camera

Step S704: Determine whether the network camera is successfully connected. When it is determined that the connection has been successfully made, then step S705 is performed. Otherwise, it returns to step S703.

Step S705: playing a webcam image.

Step S706: Receive WIFI GeGe data and environmental detection data.

Step S707: Stylized algorithm.

Step S708: Displaying to an interface.

Step S709: determining whether the detected radiation value exceeds a radiation boundary. When it is determined that the radiation value exceeds the radiation boundary, step S710 is performed. Otherwise, it returns to step S706.

Step S710: A warning message is issued.

Step S711: Wait for the direction button to be triggered.

Step S712: Determine whether the direction button is successfully triggered. When the button is successfully triggered, step S713 is performed. Otherwise, it returns to step S711.

Step S713: WIFI transmission direction data.

The applicant can know from the experimental results that the radiation sensing value of the tool has been calibrated. Later, compared with professional radiation detectors, the overall error rate is about 4.2%, which can provide a sensitive response to the local radiation changes. The remaining sensing components are professionally calibrated before leaving the factory. The transmission distance of the system can be remotely controlled and monitored by the measured wireless network (3G/WIFI), ideal for remote control across regions.

Common detectors typically need to be measured close to the source during the measurement process. When entering a regional environment, there are often hidden negative types of negative environmental factors. If the environment has high distances and destructive factors, the detector will not be able to perform immediate protection measures and will cause irreparable damage to the cells. The detection of unmanned, integrated and remotely controlled control is bound to become a future trend. With the experiment of the present invention, it is possible to develop a high-distance unmanned detection tool, which is expected to be applied and replace the traditional manual measurement in the future, thereby reducing unnecessary casualties. .

In summary, the spirit of the present invention is mainly to design an environmental monitoring system, which is composed of a portable environment measuring device and a remote server. The portable environment measuring device can be inserted into at least one of the plurality of removable measuring modules. The user can measure different environmental parameters by replacing the above-mentioned replaceable measurement module. For example, radiation intensity, luminosity, electromagnetic strength, temperature, humidity, and toxic gas concentration, and the like. Moreover, the portable environment measuring device is configured with a wireless network transmission module, and can output a plurality of measured environmental parameters to the remote server through a network interface. In addition, the remote server is used to record the above environmental parameters to understand environmental changes, such as whether the concentration of toxic gases continues to increase to prevent dangers from occurring in advance. In addition, the user can log in to the remote server through the network and monitor the change of the environmental parameters through a software interface.

Moreover, in order to cope with a crisis, personnel cannot enter dangerous areas. At the inspection site, the portable environment measuring device is provided with a camera and a motion module, and the action module can be driven by a tire or a flight module. The user can log in to the remote server to remotely control the portable environment measuring device to enter the environmental parameters of the inspected site in the dangerous area. For example, if the radioactive material leaks, the user can control the portable environmental measuring device to enter the radioactive substance leakage area to measure the radiation intensity to confirm whether the person can enter the treatment.

The specific embodiments of the present invention are intended to be illustrative only and not to limit the invention to the above embodiments, without departing from the spirit of the invention and the following claims. The scope of the invention and the various changes made are within the scope of the invention. Therefore, the scope of the invention is defined by the scope of the appended claims.

101‧‧‧Remote Server

102‧‧‧ portable environmental measuring device

1021, 201‧‧‧ slots

1022, 202‧‧‧ control circuit

1023, 203‧‧‧Wireless Network Transmission Module

204‧‧‧Global Positioning System Module

205‧‧‧Mobile Module

206‧‧‧Image capture module

301‧‧‧Right block

302‧‧‧Screen block

303‧‧‧left block

304‧‧‧Upper block

401‧‧‧Users

402‧‧‧Smart system side

403‧‧‧Web server

404‧‧‧Microprocessor

405‧‧‧Remote vehicle

406‧‧‧Detection circuit

407‧‧‧Webcam

501‧‧‧Microprocessor

502‧‧‧Wireless Transmission Module

503‧‧‧Wireless Router

504‧‧‧Web server

S601~S618‧‧‧ The steps of the firmware flow of the experiment conducted by the present invention.

S701~S713‧‧‧ The steps of the software flow of the experiment conducted by the present invention.

1 is a circuit block diagram of an environmental monitoring system according to a first embodiment of the present invention.

2 is a circuit block diagram of a portable environment measuring device according to a second embodiment of the present invention.

3 is a schematic diagram of a remote server according to a second embodiment of the present invention.

Figure 4 is a system architecture diagram of the prototype of the experiment.

Figure 5 is a schematic diagram of the wireless transmission setting of the experiment.

Figure 6 is a flow chart of the firmware of the experiment.

Figure 7 is a software flow diagram of the experiment.

101‧‧‧Remote Server

102‧‧‧ portable environmental measuring device

1021‧‧‧ slots

1022‧‧‧Control circuit

1023‧‧‧Wireless Network Transmission Module

Claims (10)

An environmental monitoring system includes: a remote server; and a portable environment measuring device, comprising: at least one slot for inserting at least one of the plurality of removable measuring modules The module, wherein each of the removable measurement modules is configured to measure different environmental parameters; a control circuit coupled to the at least one slot for receiving the extractable in the at least one slot The environmental parameter measured by the measurement module; and a wireless network transmission module coupled to the control circuit, receiving the environmental parameter measured by the removable measurement module, and transmitting the quantity through a network interface The measured environmental parameter is output to the remote server, wherein the remote server is configured to record the measured environmental parameter and the amount of change thereof, and when the measured environmental parameter changes by more than a predetermined value The remote server initiates an alert function. The environmental monitoring system of claim 1, wherein the portable environment measuring device comprises: a global positioning system coupled to the control circuit for performing a positioning to obtain the portable environment measuring device a location information, wherein the control circuit transmits the location information to the remote server through the wireless network transmission module. The environmental monitoring system of claim 1, wherein the portable environmental measuring device comprises: a mobile module coupled to the control circuit for carrying the portable environment measuring device, wherein the user operates the remote server and controls the mobile module through the network interface to move the environment Monitoring System. The environmental monitoring system of claim 1, wherein the portable environment measuring device comprises: an image capturing module coupled to the control circuit for performing image capturing, wherein the control circuit And transmitting, by the wireless network transmission module, the image captured by the image capturing module to the remote server. The environmental monitoring system of claim 1, wherein the replaceable measurement module comprises at least one of the following: a radiation intensity measurement module; a light measurement module; and an electromagnetic intensity measurement Module; a temperature measuring module; a humidity measuring module; a toxic gas concentration measuring module; a smoke measuring module; and a fire warning module. A portable environment measuring device for transmitting the measured environmental parameters to a remote server, wherein the portable environment measuring device comprises: At least one slot for inserting at least one of the plurality of removable measurement modules, wherein each of the replaceable measurement modules is configured to measure different environments a control circuit coupled to the at least one slot for receiving environmental parameters measured by the removable measurement module in the at least one slot; and a wireless network transmission module coupled to the control The circuit receives the environmental parameters measured by the replaceable measurement module, and outputs the measured environmental parameters to the remote server through a network interface, wherein the remote server records the above The measured environmental parameter and the amount of change thereof, when the measured amount of the environmental parameter changes exceeds a predetermined value, the remote server initiates a warning function. The portable environment measuring device of claim 6, wherein the portable environment measuring device comprises: a global positioning system coupled to the control circuit for performing a positioning to obtain the portable A location information of the environmental measurement device, wherein the control circuit transmits the location information to the remote server through the wireless network transmission module. The portable environment measuring device of the sixth aspect of the invention, wherein the portable environment measuring device comprises: a mobile module coupled to the control circuit for carrying the portable environment measuring device, The user operates the remote server and controls the mobile module through the network interface to move the environment monitoring system. The portable environment measuring device of the sixth aspect of the invention, wherein the portable environment measuring device comprises: an image capturing module coupled to the control circuit for performing image capturing, wherein The control circuit transmits the image captured by the image capturing module to the remote server through the wireless network transmission module. The portable environmental measuring device of claim 6, wherein the removable measuring module comprises at least one of the following: a radiation intensity measuring module; a light measuring module; Electromagnetic intensity measurement module; a temperature measurement module; a humidity measurement module; a toxic gas concentration measurement module; a smoke measurement module; and a fire warning module.