JP2023130039A - gas remote monitoring system - Google Patents

Abstract

To provide a monitoring system capable of monitoring whether or not a worker is exposed to a noxious gas from a remote site at a real time, and quickly notifying an administrator of information on the fact if exposed.SOLUTION: A monitoring system comprises: a potable type gas monitor 1; a GPS mounting portable terminal 2 that is connected to this gas monitor 1 in radio, receives gas information g from the gas monitor 1, and transmits the gas information g and position information p to a management server 3; and a management server 3 that stores the gas information g and the position information p transmitted from the portable terminal 2, in which the gas information g and the position information p on a wave page provided by the management server 3 can be monitored. The management server 3 transmits a warning mail to which the gas information g and the position information p are attached, to a communication terminal T of an administrator when a gas concentration is at an abnormal value level and the management server receives the gas information g and the position information p requiring outgoing of the warning.SELECTED DRAWING: Figure 1

Description

In order to protect the safety of workers working in environments where toxic gases or oxygen depletion may occur, the present invention enables remote locations to detect whether workers are exposed to toxic gases or oxygen-deficient atmospheres. This relates to a gas remote monitoring system that enables real-time monitoring of gas exposure and allows for appropriate and prompt response in the event of exposure.

Workers who work in environments where toxic gases may be generated typically carry portable gas monitors to ensure their safety. Conventional portable gas monitors issue alarms when toxic gases are detected. However, this alarm is intended for workers who carry gas monitors, and some gas monitors store measured values inside the gas monitor itself, but in any case, the administrator must Unless you are in the area, you cannot immediately know the gas information. As a result, it is not possible to prevent accidents in which workers ignore gas monitor alarms and become gas poisoning, and it is also not possible to prevent workers who are unable to move due to gas poisoning to locate them and take appropriate measures. It is also impossible to carry out rescue operations.

In order to solve this problem, the following has been proposed as a monitoring system or a danger alarm system for notifying the outside (such as a manager) of information detected by a gas monitor.
Patent Document 1 discloses that docking stations are distributed and installed in predetermined areas to be monitored, gas monitors are set on the docking stations, the information is aggregated on a data server, and the results are analyzed and communicated to the outside. Monitoring systems have been proposed that (for example, send a warning message to security personnel).

Further, Patent Document 2 discloses a portable dangerous device equipped with a current position detection unit, a surrounding gas concentration detection unit, a notification information generation unit that generates notification information indicating that the gas concentration exceeds a threshold value, etc. A worker at the site is provided with a notification device, and the portable danger notification device transmits the notification information along with location information to the danger notification device (management server), and the danger notification device determines the degree of danger of the worker. In addition, a danger alarm system has been proposed that notifies the occurrence of gas and its location to a portable information terminal device carried by a person (worker or other person) near the site.

Japanese Patent Application Publication No. 2012-175709 Japanese Patent Application Publication No. 2004-280262

However, the above-mentioned conventional technology has the following problems.
The system disclosed in Patent Document 1 aggregates gas monitor information to a data server via a docking station, analyzes the results, and sends warning messages, etc.; however, (i) a dedicated device such as a docking station is required; ,Moreover, it is necessary to install docking stations,distributed in the predetermined areas where monitoring is,conducted, resulting in poor versatility and high equipment costs.,(ii) Gas monitors need to be set in docking stations. There are problems such as lack of real-time performance and (iii) the gas information obtained is not correlated with location information.In particular, problems (ii) and (iii) mean that the user is being exposed to toxic gas at the moment. The administrator cannot know detailed information about the worker.
Further, the system of Patent Document 2 also requires a dedicated portable danger alarm device, so it lacks versatility and increases equipment cost.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to obtain gas information and position information of the point where a worker is working without using special equipment, and to enable the worker to avoid poisonous gas or oxygen. A gas monitoring system that can monitor in real time whether or not a person is exposed to a deficient atmosphere from a remote location, and if they are exposed, can immediately notify managers of gas information and location information. It is about providing.

In order to solve the above problems, the present invention has the following features.
[1] A portable gas monitor (1) that is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and uses this information as location information (g) obtained using the GPS function. A GPS-equipped mobile terminal (2) that transmits the gas information (g) and its location information (p) to the management server (3) after associating it with p); a management server (3) that stores gas information (g) and location information (p);
A gas remote monitoring system characterized in that gas information (g) and location information (p) can be monitored in real time on a web page provided by a management server (3).
[2] In the gas remote monitoring system described in [1] above, the gas information (g) and location information (p) stored in the management server (3) are displayed on the map of the web page provided by the management server (3). A gas remote monitoring system characterized by a display.

[3] A portable gas monitor (1) that is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and uses this information as location information (g) acquired by the GPS function. A GPS-equipped mobile terminal (2) that transmits the gas information (g) and its location information (p) to the management server (3) after associating it with p); a management server (3) that stores gas information (g) and location information (p);
When the management server (3) receives gas information (g) and location information (p) in which the gas concentration is at an abnormal level and requires an alarm, the management server (3) sends a message to the administrator whose e-mail address has been registered in advance. A gas remote monitoring system characterized by transmitting an alarm email with gas information (g) and location information (p) attached to a terminal (T).

[4] A portable gas monitor (1) that is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and uses this information as location information (g) acquired by the GPS function. A GPS-equipped mobile terminal (2) that transmits the gas information (g) and its location information (p) to the management server (3) after associating it with p); a management server (3) that stores gas information (g) and location information (p);
In addition to being able to monitor gas information (g) and location information (p) in real time on the web page provided by the management server (3),
When the management server (3) receives gas information (g) and location information (p) in which the gas concentration is at an abnormal level and requires an alarm, the management server (3) sends a message to the administrator whose e-mail address has been registered in advance. A gas remote monitoring system characterized by transmitting an alarm email with gas information (g) and location information (p) attached to a terminal (T).

[5] In the gas remote monitoring system described in [4] above, the gas information (g) and location information (p) stored in the management server (3) are displayed on the map of the web page provided by the management server (3). A gas remote monitoring system characterized by a display.
[6] In any of the gas remote monitoring systems described in [3] to [5] above, the management server (3) sends messages to the administrator's communication terminal (T) according to the gas concentration in the gas information (g). , a gas remote monitoring system characterized in that two or more levels of alarm mail with different alarm levels are sent.
[7] The gas remote monitoring system according to any one of [3] to [6] above is characterized in that a dead time is provided for sending an alarm email from the management server (3) to the administrator's communication terminal (T). gas remote monitoring system.

[8] In the gas remote monitoring system according to any of [3] to [7] above, the GPS-equipped mobile terminal (2) receives gas information (g) and its position information (p) from the portable gas monitor (1). ) in a fixed form to the management server (3), and when predetermined gas information (g) whose gas concentration is at an abnormal value level is received from the portable gas monitor (1), the relevant gas information (g) and its position information (p) is immediately transmitted to a management server (3) by interrupt processing.

[9] In the gas remote monitoring system described in [8] above, the GPS-equipped mobile terminal (2) receives gas information (g) from the portable gas monitor (1) at regular intervals and acquires this using the GPS function. At the same time, it is determined whether the gas concentration of the gas information (g) is at an abnormal value level, and the gas information (g) and its position information (p) are linked to the management server ( 3) in accordance with the conditions in (i) and (ii) below,
(i) At fixed time intervals, all the gas information (g) and its position information (p) received from the portable gas monitor (1) within the fixed time are collectively transmitted to the management server (3).
(ii) When gas information (g) whose gas concentration is at an abnormal value level and satisfies certain conditions is received from the portable gas monitor (1), the gas information (g) and its position information (p) are It is immediately transmitted to the management server (3) as information requiring an alarm.
When the management server (3) receives the gas information (g) and location information (p) in (ii) above, the management server (3) sends the gas information (g) and location information (p) to the administrator's communication terminal (T). A remote monitoring system characterized by sending a warning email with an attached message.

[10] In the gas remote monitoring system described in [9] above, the GPS-equipped mobile terminal (2) detects that the gas concentration in the gas information (g) is an abnormal value using the gas concentration threshold set in one or more stages. In addition to determining whether the gas information (g) is at the level, the gas information (g) is compared with the previously received gas information (g ₀ ), and the gas information (g) satisfies the conditions (a) and (b) below. In this case, the gas information (g) and its location information (p) are sent to the immediate management server (3) as information that requires an alarm, and the gas information (g) meets the following (a) and (c). If the conditions are met, the gas information (g) and location information (p) received after a predetermined period of time have passed since the previous transmission of the gas information (g) and location information (p) that required an alarm to the management server (3). A gas remote monitoring system characterized in that p) is immediately transmitted to a management server (3) as information requiring an alarm.
(a) The gas concentration in gas information (g) is at an abnormal value level.
(b) The abnormal value level of the gas concentration in the gas information (g) is at least one step higher than the abnormal value level of the gas concentration in the previously received gas information (g ₀ ). (Including the case where the gas concentration of _g0 ) is not at an abnormal value level, but the gas concentration of gas information (g) is at an abnormal value level.)
(c) The abnormal value level of the gas concentration in the gas information (g) is the same level as the abnormal value level of the gas concentration in the previously received gas information (g ₀ ), or is at least one step lower. .

[11] In any of the gas remote monitoring systems described in [1] to [10] above, the GPS-equipped mobile terminal (2) selectively wirelessly communicates with portable gas monitors (1) from multiple manufacturers using one application. A gas remote monitoring system characterized by being connectable.
[12] Using any of the gas remote monitoring systems described in [1] to [11] above, the system uses the gas information (g) and location information (p) stored in the management server (3) to detect harmful gases within the facility. A method for identifying a hazardous gas leak location, characterized by identifying a gas leak location.

The gas remote monitoring system of the present invention acquires gas information and location information at the point where a worker is working without using special equipment, and remotely determines whether the worker is exposed to toxic gas or an oxygen-deficient atmosphere. It can be monitored in real time from the ground, and if exposed, gas information and location information can be immediately notified to managers. This makes it possible to appropriately and quickly respond to warnings to workers, confirmation of their safety, rescue, etc. Additionally, as the equipment configuration requires only a portable gas monitor with a wireless communication function and a general-purpose GPS-equipped mobile terminal, there is no need for specialized equipment as used in conventional technology, resulting in a low-cost system. .
Furthermore, according to the present invention, gas information and location information are associated (linked) and stored in the management server, and data accumulated over a certain period of time can be obtained, so it is possible to determine the location of toxic gas generation and the type and concentration of gas. can be understood quantitatively, and therefore it is also possible to identify toxic gas leak points that require repair (leak points due to aging equipment, etc.).

System configuration diagram showing one form of the gas remote monitoring system of the present invention A block diagram for explaining the configuration and functions of a portable gas monitor and a GPS-equipped mobile terminal in an embodiment of the gas remote monitoring system of the present invention. A block diagram for explaining the configuration and functions of a management server in an embodiment of the gas remote monitoring system of the present invention An explanatory diagram showing the processing form of gas information g in the GPS-equipped mobile terminal and the timing of data transmission to the management server in the embodiment of FIG. 2 An explanatory diagram showing an example of a real-time display screen (real-time monitoring screen) in which gas information and location information are displayed on a map of a web page provided by the management server in the embodiment of FIG. 2 In the embodiment shown in FIG. 2, when a dead time is set for sending an alarm email, the change in gas concentration in the gas information g that the GPS-equipped mobile terminal receives from the portable gas monitor and the transmission of the alarm email from the management server. Explanatory diagram illustrating timing An explanatory diagram showing an example of a warning email sent from the management server to the administrator's communication terminal in the embodiment of FIG. 2 An explanatory diagram showing an example of a search screen when searching for data (gas information g and location information p) stored in the management server on a web page in the embodiment of FIG. 2

FIG. 1 is a system configuration diagram showing one form of the gas remote monitoring system of the present invention. This monitoring system is wirelessly connected to a portable gas monitor 1, receives gas information g from the portable gas monitor 1, associates this with position information p acquired by the GPS function, and then The management server includes a GPS-equipped mobile terminal 2 that transmits the gas information g and position information p to the management server 3, and a management server 3 that stores the gas information g and position information p transmitted from the GPS-equipped mobile terminal 2. In addition to making it possible to monitor gas information g and position information p in real time on the web page provided (generated) by the management server 3, the management server 3 also monitors gas information g and position information p in real time on the web page provided (generated) by the management server 3. In addition, when receiving gas information g and location information p that require an alarm, an alarm email with the gas information g and location information p is immediately sent to the communication terminal T of the administrator whose email address has been registered in advance. It was designed to be sent. Here, in the present invention, "gas information g and its position information p" and "gas information g and position information p" refer to gas information g and position information p associated as described above in the GPS-equipped mobile terminal 2. shall refer to.

Further, a gas remote monitoring system according to another embodiment of the present invention includes a portable gas monitor 1 as described above, a GPS-equipped mobile terminal 2, and a management server 3, and [i] the management server 3 provides (generates) [ii] The management server 3 allows gas information g and position information p to be monitored in real time on a web page, and when the gas concentration is at an abnormal value level (for example, a value exceeding a threshold value) and an alarm is required to be issued. When gas information g and location information p are received, an alarm email with the gas information g and location information p is immediately sent to the communication terminal T of the administrator whose email address has been registered in advance. It was designed so that something could be done.

The GPS-equipped mobile terminal 2 is, for example, a smartphone or a mobile phone. The portable gas monitor 1 and the GPS-equipped mobile terminal 2 are basically carried by one worker, so that the gas information g obtained by the portable gas monitor 1 and the GPS function of the GPS-equipped mobile terminal 2 are obtained. Location information p can be associated (linked) and used.
Note that since one ID is normally provided for each GPS-equipped mobile terminal, it is possible to monitor multiple sets of GPS-equipped mobile terminals 2 + portable gas monitor 1 (multiple workers).
The portable gas monitor 1 may be one that has conventionally used general functions, but since it will be connected to the GPS-equipped mobile terminal 2 by short-range wireless connection, the ) must be prepared. Although any short-range wireless connection method may be used, Bluetooth (registered trademark) is particularly preferable because it connects wirelessly to a GPS-equipped mobile terminal carried by the same worker. Therefore, in this embodiment, a case will be explained in which the GPS-equipped mobile terminal 2 is connected to the portable gas monitor 1 by short-range wireless connection via Bluetooth.

The portable gas monitor 1 can measure different types of gases depending on the model (i) (particularly models made by different manufacturers; the same applies hereinafter); and (ii) the usability of the portable gas monitor 1 in the gas measurement area (factory, etc.) varies depending on the model. 〈iii〉Due to differences in cost and reliability depending on the model, it is better not to limit your use to just one model, so it is recommended to make it possible to selectively use different models of portable gas monitors. preferable. For this reason, the GPS-equipped mobile terminal 2 is designed to be able to selectively connect to multiple models (multiple manufacturers) of portable gas monitors 1 using one application. In this case, an application is created to match the Bluetooth communication protocol of each model (manufacturer), and allows the user to select the model (single model) to be used from among multiple connectable models.
In this way, the equipment configuration of the monitoring system of this embodiment uses a Bluetooth-compatible portable gas monitor 1 and a general-purpose GPS-equipped mobile terminal 2, without using a dedicated device such as a portable danger detection device. The installed mobile terminal 2 is characterized in that it can be connected to multiple models (multiple manufacturers) of portable gas monitors 1 using one application.

The GPS-equipped mobile terminal 2 receives gas information g from the portable gas monitor 1 at regular intervals (for example, every 2 seconds), and associates (links) this gas information g with the position information p acquired by its own GPS function. ) and transmitting the data to the management server 3. Preferably, as a data transmission function to the management server 3, (1) the gas information g and its position information p received from the portable gas monitor 1 are sent to the management server in a certain format; 3 (regular data transmission); (2) When predetermined gas information g whose gas concentration is at an abnormal value level is received from the portable gas monitor 1, the gas information g and its position information p are transmitted by interrupt processing. It has a function of immediate transmission to the management server 3 (immediate transmission of abnormal data). Here, data transmission in (2) above is performed at a predetermined time when the gas concentration is at an abnormal value level, regardless of the steady data transmission in (1) above, in order to notify that the gas concentration is such that an alarm is required. This is executed immediately when gas information g is received from the portable gas monitor 1.

In a more specific and preferred embodiment, the GPS-equipped mobile terminal 2 determines whether the gas concentration of the gas information g is at an abnormal value level (e.g., determination using a gas concentration threshold), and It has a function of transmitting gas information g and its position information p to the management server 3 according to the conditions (i) and (ii) below.
(i) In order to reduce battery consumption of the GPS-equipped mobile terminal 2, all gas information g received from the portable gas monitor 1 and its The location information p is sent to the management server 3 all at once. That is, the steady data transmission described in (1) above is performed.
(ii) When gas information g whose gas concentration is at an abnormal value level and satisfies certain conditions is received from the portable gas monitor 1, the gas information g and its position information p are immediately managed as information that requires an alarm to be issued. Send to server 3. That is, the abnormal data in (2) above is immediately transmitted.

In a more specific and preferred embodiment, the GPS-equipped mobile terminal 2 determines whether the gas concentration in the gas information g is at an abnormal value level using gas concentration thresholds set in one or more stages. At the same time, the gas information g is compared with the previously received gas information g ₀ (that is, when gas information g is received from the portable gas monitor 1 every 2 seconds, the gas information g ₀ received 2 seconds ago). , when the gas information g satisfies the following conditions (a) and (b), the gas information g and its location information p are sent to the immediate management server 3 as information requiring alarm transmission, and the gas information g is If the following conditions (a) and (c) are met, the gas information g and its location information received after a predetermined period of time from the time when the gas information g and location information p that required an alarm to be sent to the management server 3 last time. It has a function of immediately transmitting p to the management server 3 as information requiring an alarm.
(a) The gas concentration of gas information g is at an abnormal value level.
(b) The abnormal value level of the gas concentration of the gas information g is at least one level higher than the abnormal value level of the gas concentration of the previously received gas information _g0 . However, this case also includes a case where "the gas concentration of gas information _g0 is not at the abnormal value level, but the gas concentration of gas information g is at the abnormal value level".
(C) The abnormal value level of the gas concentration of the gas information g is the same level as the abnormal value level of the gas concentration of the previously received gas information _g0 , or is at least one step lower.

In addition, when determining whether the gas concentration is at an abnormal value level using the gas concentration threshold, if the measurement target by the portable gas monitor 1 is a toxic gas such as CO, the gas concentration below the threshold is considered normal. On the other hand, when the measurement target is oxygen, the gas concentration above the threshold is a normal value, and the gas concentration below the threshold is an abnormal value. In the embodiment, a case where the measurement target is a toxic gas such as CO, a gas concentration below a threshold value is a normal value, and a gas concentration exceeding the threshold value is an abnormal value will be described.

The management server 3 stores gas information g and position information p transmitted from the GPS-equipped mobile terminal 2 in association with each other. This gas information g and location information p are sequentially posted on a web page provided (generated) by the management server 3, and an administrator or the like accesses this web page using a communication terminal _TX with a display such as a personal computer or a mobile terminal. This allows you to monitor web pages in real time. In other words, it is possible to remotely monitor in real time whether a worker carrying a gas monitor is exposed to toxic gas. In this web page, gas information g and location information p are displayed on a map.

The management server 3 receives gas information g and position information p in which the gas concentration is at an abnormal value level (for example, a value exceeding a threshold value) and requires an alarm to be issued, such as gas information g and position information p in (ii) above. When received, the gas information g with warning and location information p will be posted on the web page, and will be immediately sent to the communication terminal T such as the administrator's PC or smartphone whose email address has been registered in advance. An alarm email with the gas information g and location information p attached is sent.
That is, the management server 3 stores the gas information g and location information p transmitted from the GPS-equipped mobile terminal 2, posts it on the web page, and sends an alarm email with the gas information g and location information p to the administrator's communication. It has the function of sending to terminal T.

By sending the above warning email, the manager is notified that the worker carrying the gas monitor has been exposed to toxic gas. This makes it possible to respond appropriately and quickly, such as warning workers, confirming their safety, and providing rescue services.For example, it is possible to prevent disasters such as workers ignoring gas monitor alarms and becoming gas poisoning. In addition, by identifying the location of workers who are unable to move due to gas poisoning, it is possible to quickly rescue workers and reduce the extent of damage caused by the disaster.
Further, gas information g and position information p for a certain period (for example, about one year) are stored in the management server 3 in association with each other (linked). With this accumulated data, it is possible to quantitatively understand the location where toxic gases are generated, as well as the type and concentration of gases, which makes it possible to identify toxic gas leak points that require repair (leak points due to aging equipment, etc.). is also possible.
The management server 3 may be installed at a management center or the like, or may be installed on an online storage.

FIG. 2 (FIGS. 2-1 and 2-2) is for explaining the configuration and functions of a portable gas monitor 1, a GPS-equipped mobile terminal 2, and a management server 3 in an embodiment of the gas remote monitoring system of the present invention. FIG.
The portable gas monitor 1 has the functions of a general gas monitor, and therefore includes a gas sensor 10, a gas information generating section 11, a display processing section 12, a display section 13, etc. A communication unit 14 (bluetooth communication unit) is provided for performing short-range wireless communication with the GPS-equipped mobile terminal 2.

The GPS-equipped mobile terminal 2 serves as a terminal controller, and includes a short-range communication section 20 that receives gas information g transmitted by Bluetooth from the portable gas monitor 1, a GPS acquisition section 26 that obtains position information p by GPS, and a portable gas monitor 1. The information processing unit 21 associates (links) the gas information g received from the GPS with the position information p acquired by GPS, determines whether the gas concentration of the gas information g is at an abnormal value level, and determines whether the gas concentration of the gas information g is at an abnormal value level. An abnormal data determination unit 22 that provides dead time under predetermined conditions for transmission to the management server 3 when the gas concentration is at an abnormal value level, a transmission data generation unit 23 that creates data to be transmitted to the management server 3, and a management server. 3, and a long-distance communication section 25 that transmits the associated gas information g and position information p to the management server 3 via a mobile phone communication line, the Internet, etc.

The GPS-equipped mobile terminal 2 further includes a terminal input section 27a, a terminal output section 27b, a terminal control section 27c, and a terminal storage section 27d, and also includes a touch panel 28a, a display 28b, and a speaker 28c as input/output devices. . The terminal control unit 27c executes an application program installed on the computer in the mobile terminal and controls the entire terminal. The terminal storage unit 27d is configured to be able to store various information.
As mentioned earlier, this GPS-equipped mobile terminal 2 has an application created to be compatible with the Bluetooth communication protocols of multiple models (multiple manufacturers), and one application can handle the Bluetooth communication protocols of multiple models (multiple manufacturers). It is possible to selectively connect to the portable gas monitor 1.

The management server 3 transmits gas abnormality data from among the data transmitted from the GPS-equipped mobile terminal 2, that is, data transmission of gas information g and position information p whose gas concentration is at an abnormal value level and requires an alarm transmission (as described above). 2), the transmission data discriminator 30 determines the immediate transmission of abnormal data), creates an alarm email with the gas information g and position information p of the gas abnormal data transmission determined by the transmission data discriminator 30, and sends it. An alarm mail generation unit 31 that sends the information to the administrator's communication terminal T, a database unit 32 that stores the gas information g and location information p sent from the GPS-equipped mobile terminal 2, and a database unit 32 that stores the gas information g and location information p. The web page generating section 33 includes a web page generating section 33 that generates a web page, and a web server section 34 that provides the web page generated by the web page generating section 33 to the outside via the Internet. Further, the database section 32 includes a gas information database 320 and a location information database 321, and the web page generation section 33 includes a gas information management section 330 and a location information management section 331. Further, communication with the GPS-equipped mobile terminal 2 and the communication terminal _TX , and transmission of an alarm email to the communication terminal T are all performed via the communication module 35.

Next, the actual usage and operation of the monitoring system according to the embodiment described above will be explained. In the following explanation, the time intervals and dead times of data transmission are described as every 2 seconds, every 10 minutes, 5 minutes, and 2 minutes, but the time intervals and dead times of data transmission are limited to these. It is not a fixed value, but a value that can be set arbitrarily. The same applies to the gas concentration threshold (CO concentration 50 ppm, 100 ppm).
The portable gas monitor 1 is equipped with conventionally used general functions, and a gas information generation section 11 generates gas information g based on the gas concentration detected by the gas sensor 10. is transmitted to the GPS-equipped mobile terminal 2 via the communication unit 14 every two seconds.

Usually, the portable gas monitor 1 and the GPS-equipped portable terminal 2 are carried by one worker, and the worker turns on the portable gas monitor 1 and launches the application installed on the GPS-equipped portable terminal 2. At this time, the application can selectively connect to portable gas monitors 1 of multiple models (multiple manufacturers), so you can select which manufacturer and model number to connect to, and connect the portable gas monitor 1. Start communication with 1. When communication is started, gas information g acquired by the portable gas monitor 1 is transmitted to the GPS-equipped mobile terminal 2 every two seconds.

Gas information g transmitted from the portable gas monitor 1 to the GPS-equipped mobile terminal 2 every two seconds is processed in the GPS-equipped mobile terminal 2 as follows.
The gas information g received through the short-range communication unit 20 is associated (linked) with the position information p acquired by the GPS acquisition unit 26 in the information processing unit 21, and then the gas information g and position information p are , is sent to the transmission data generation unit 23 to generate steady transmission data, and "regular transmission data" including all the gas information g and position information p within that time is generated every 10 minutes. This regular transmission data is then transmitted from the transmission control unit 24 to the management server 3 at intervals of 10 minutes. That is, 10 minutes of data (gas information g and position information p) are transmitted in batches at 10 minute intervals. The reason why data is transmitted in bulk in this way is to suppress battery consumption of the GPS-equipped mobile terminal 2.

Apart from the above-mentioned regular transmission data, gas information g and position information p are sent from the information processing section 21 to the abnormal data determination section 22 every 2 seconds. In this abnormal data determination unit 22, the gas concentration threshold is set at two levels, and the threshold for CO concentration at level 1 (first alarm level) is 50 ppm, and the threshold for level 2 (second alarm level) is: 100 ppm is set, and as a result, a CO gas concentration of more than 50 ppm and less than 100 ppm becomes an "abnormal value level 1", and a CO gas concentration of more than 100 ppm becomes an "abnormal value level 2". The abnormal data determination unit 22 uses these thresholds to determine whether the gas concentration of the gas information g is at the abnormal value level, and when the gas concentration of the gas information g is at the abnormal value level, a predetermined value is determined. After a dead time is set under the conditions of "Immediate transmission data" to be immediately transmitted to the management server 3 is generated as information that requires transmission. Then, this immediate transmission data is immediately transmitted from the transmission control unit 24 to the management server 3. Here, the dead time described above is provided because the management server 3 sends an alarm email to the administrator's communication terminal T based on the reception of the "immediate transmission data". This is to prevent continuous transmission of . This is because, as will be described later, if alarm emails are continuously sent to the administrator's communication terminal T, a large amount of battery of the communication terminal T will be consumed.

FIG. 3 shows the processing form of gas information g in the GPS-equipped mobile terminal 2 and the timing of data transmission to the management server 3 in this embodiment. To explain the operation of the monitoring system of this embodiment based on this FIG. The information is collectively transmitted to the management server 3 as data. Completely apart from this regular data transmission at 10 minute intervals, abnormal data is transmitted to the management server 3 in the following manner in order to notify the administrator's communication terminal T of an alarm. That is, the gas information g sent to the abnormal data determination unit 22 is determined whether the gas concentration is at the abnormal value level using the gas concentration threshold (step S1), and it is determined that the gas concentration is not at the abnormal value level. In this case, transmission to the management server 3 is not performed. On the other hand, if it is determined that the gas concentration is at an abnormal value level, the abnormal value level of the gas concentration of the gas information g is the same as the abnormal value level of the gas concentration of the gas information g ₀ that was previously received (received 2 seconds ago). (step S2), and if the level is one level or more higher than the abnormal value level of gas information g ₀ , for example, if the gas concentration of the gas information g is "abnormal value level 2" and the gas of gas information g ₀ is When the concentration is "abnormal value level 1" or when the gas concentration of the relevant gas information g is "abnormal value level 1" and the gas concentration of gas information g ₀ is not at the abnormal value level, the relevant gas information g and its The position information p is sent to the immediate management server 3 as information that requires an alarm to be issued. On the other hand, if the abnormal value level of the gas information g is the same level as the abnormal value level of the gas information g ₀ , or is at least one step lower, for example, the gas concentration of the gas information g is "abnormal". In some cases, the gas concentration of gas information g ₀ is "abnormal value level 1" and the gas concentration of gas information g 0 is "abnormal value level 1," or the gas concentration of gas information g 0 is "abnormal value level 1" and the gas concentration of gas information g ₀ is "abnormal value level 1." If the level is "level 2", the elapsed time from the time when the gas information g and position information p that required an alarm to be sent to the management server 3 was previously sent is checked (step S3), and the specified Dead time will be provided. That is, if a predetermined period of time has not elapsed since the gas information g and position information p that required an alarm to be sent to the management server 3 last time, the information is not transmitted to the management server 3. On the other hand, if a predetermined period of time has elapsed since the last time gas information g and position information p that required an alarm transmission were sent to the management server 3, the gas information g and its position information p do not require an alarm transmission. It is immediately transmitted to the management server 3 as required information.

Here, as the "predetermined time" of the dead time, the gas concentration of gas information In the case of "value level 1", the period is set to 5 minutes, and in the case of "abnormal value level 2", it is set to 2 minutes. In other words, when the gas concentration of gas information g is "abnormal value level 1", if more than 5 minutes have passed since the last time gas information g and position information p that required an alarm were sent to the management server 3, , the gas information g and the position information p are transmitted to the immediate management server 3 as information that requires an alarm to be issued. In addition, when the gas concentration of gas information g is "abnormal value level 2", if more than 2 minutes have passed since the last time gas information g and position information p that required an alarm were sent to the management server 3, , the gas information g and the position information p are transmitted to the immediate management server 3 as information that requires an alarm to be issued.

In the management server 3, the data of gas information g and position information p (regular transmission data, instant transmission data) received from the GPS-equipped mobile terminal 2 through the communication module 35 is stored in the database section 32. Based on this, the following (I) and (II) are executed.
(I) The gas information g and location information p received from the GPS-equipped mobile terminal 2 are posted one after another on a web page provided (generated) by the management server 3, and the gas information g and location information p are displayed in real time on this web page. to enable monitoring. Administrators and others can perform this kind of real-time monitoring by accessing a web page using a communication terminal _TX with a display, such as a computer or mobile device.
(II) When receiving gas information g and position information p (i.e., instantaneous transmission data from the GPS-equipped mobile terminal 2) in which the gas concentration is at an abnormal value level and requires alarm transmission from the GPS-equipped mobile terminal 2, A warning email with the gas information g and location information p is sent to the communication terminal T (computer, smartphone, etc.) of the administrator whose email address is registered in , and the worker is exposed to toxic gas. Notify the administrator. In this case, it is preferable that an alarm email with two or more different alarm levels is sent to the administrator's communication terminal T according to the gas concentration of the gas information g.

Regarding (I) above, the web page generation unit 33 generates a web page on which gas information g and position information p (preferably gas information g and position information p with an alarm) are posted. The web page has a format in which gas information g and location information p are displayed on a map. As the map, for example, Google (registered trademark) Maps can be used, and in that case, map data is acquired from the Google Maps API through the communication module 35 in order to draw the position information p on Google Maps. This web page can be viewed by administrators and others by accessing the web server section 34 using a communication terminal _T can be monitored.
In addition to real-time information, past information stored in the database section 32 (for example, alarm history) can be posted on the web page, and in this case, the web page generation section 33 stores the necessary information. It is acquired from the database unit 32 (gas information database 320, position information database 321) and generates a web page. In addition, in the web page generation unit 33, information necessary for the web page (information received in real time from the GPS-equipped mobile terminal 2 and information acquired from the database unit 32) is generated by the gas information management unit 330 and the location information management unit 331, respectively. managed and used to generate web pages.

FIG. 4 shows an example of a real-time display screen (real-time monitoring screen) on which gas information g and position information p are displayed on a map of a web page. In this case, the location information of four workers (users 1, 2, 3, and 4) each carrying a portable gas monitor 1 and a GPS-equipped mobile terminal 2 is displayed as four marks on the map on the screen. Click on each mark on the map to display detailed information about the detected gas. Furthermore, the "status of each user" (gas information) and "recent alarm history" are displayed on the screen, and when the gas concentration reaches an abnormal value level (for example, CO concentration over 50 ppm), the alarm information is displayed as " "Recent alarm history" is displayed. Note that this real-time monitoring screen is not limited to that shown in FIG. 4, and can take various forms. Therefore, for example, although the real-time monitoring screen in FIG. 4 does not display warnings divided into a first-stage alarm and a second-stage alarm, such a display can be made if necessary.

Regarding (II) above, the transmission data determination unit 30 determines whether the data received from the GPS-equipped mobile terminal 2 through the communication module 35 is "regular transmission data" or "immediate transmission data" (that is, an abnormal value that requires an alarm). level gas information g and its position information p (transmission data), and if it is determined as "immediate transmission data", the alarm mail generation unit 31 generates the gas information g. An alarm email with location information p is generated and sent (immediately sent) to the administrator's communication terminal T via the mail server 4. That is, when the management server 3 receives the above-mentioned "immediate transmission data", a warning mail is automatically created and this warning mail is immediately sent to the administrator's communication terminal T. This warning email displays, for example, the type of gas and the detected gas concentration level as gas information, and the position coordinates of the detected location as position information.
Here, the alarm mail is issued in two stages (first-stage alarm and second-stage alarm) corresponding to the above-mentioned abnormal value level 1 and abnormal value level 2 of the gas concentration. That is, if the gas concentration is at abnormal value level 1 (above the threshold of level 1 to below the threshold of level 2), a first-level alarm email is sent, and then the gas concentration becomes even higher and reaches abnormal value level 2 (level 2). (exceeds the threshold), a two-stage warning email is sent as a higher-order warning.

Further, since the "immediate transmission data" transmitted from the GPS-equipped mobile terminal 2 is provided with a dead time as described above, this dead time is directly reflected in the transmission of the alarm mail. If the gas concentration continues to exceed the level 1 or level 2 threshold and alarm emails continue to be sent to the administrator's communication terminal T, a large amount of the battery of the communication terminal T may be consumed or the terminal may become inoperable. It invites. Therefore, in both 1st and 2nd stage alarm mails, once a warning mail is sent, even if the gas concentration continues to exceed the threshold, no warning mail will be sent for a certain period of time, and the warning mail will not be sent for a certain period of time. If the gas concentration still exceeds the threshold after a certain period of time, a warning email is sent again. That is, a dead time is provided for sending the warning email.

As described above, the dead time is set by the abnormal data determination unit 22 of the GPS-equipped mobile terminal 2, and is directly reflected in the transmission of the alarm email by the management server 3, thereby providing a dead time for the transmission of the alarm email. . FIG. 5 shows the transition of the gas concentration of the gas information g that the GPS-equipped mobile terminal 2 receives from the portable gas monitor 1 and the timing of sending the alarm email from the management server 3 when such a dead time is provided. This is an example, and the solid line in the figure shows the transition of the gas concentration (CO concentration in this case) of the gas information g that the GPS-equipped mobile terminal 2 successively receives from the portable gas monitor 1. In the example shown in FIG. 5, a first-stage alarm email (1a) is sent when the gas concentration exceeds the level 1 threshold (CO concentration over 50 ppm). Even if the condition continues to exceed the threshold of level 2 (but below the threshold of level 2), the alarm email will not be sent for the time t ₁ (dead time), and even after that t ₁ , the gas concentration will still be the threshold of level 1. If the value exceeds the above, the 1st stage warning email (1b) is sent again. Thereafter, even if the gas concentration continues to exceed the level 1 threshold, the first-stage alarm mail (1b) is similarly sent every _t1 . Furthermore, if the gas concentration falls below the level 1 threshold after transmitting the first stage alarm mail (1b) and then exceeds the level 1 threshold again, a first stage warning mail (1a) is sent again. Here, t ₁ (dead time) in the case of a first-stage warning mail is 5 minutes.

Thereafter, when the gas concentration further increases to a value exceeding the level 2 threshold (CO concentration exceeding 100 ppm), a second-stage warning email (2a) is immediately sent. A 2nd stage alarm is a situation where the level of danger is higher than a 1st stage alarm, and _it is necessary to notify the administrator immediately. 5 minutes), a 2-step warning email (2a) will be sent immediately. After that, even if the gas concentration continues to exceed the level 2 threshold, the alarm email will not be sent for t ₂ (dead time), and even after t ₂ , the gas concentration will still be at level 2. If the threshold is exceeded, a second-stage warning email (2b) is sent again. Thereafter, even if the gas concentration continues to exceed the level 2 threshold, a two-step alarm email (2b) is similarly sent every _t2 . As mentioned above, a 2nd stage alarm is more dangerous than a 1st stage alarm, so t ₂ (dead time) in the case of a 2nd stage alarm mail is equal to t ₁ (dead time) in the case of a 1st stage warning mail. It is set at 2 minutes, which is shorter than that.

In addition, if the gas concentration falls to exceed the level 1 threshold within 2 minutes after the second-level warning email (2a) is sent, and this condition continues, the second-level warning email (2a) ) is sent, a first-stage warning mail (1b) is sent every t ₁ (5 minutes).
Note that, as shown in FIG. 5, in both the first-stage alarm and the second-stage alarm, even if the gas concentration goes from above the threshold value to below the threshold value, an email indicating that the gas concentration has become below the threshold value is not sent. This is because, for example, even if the gas concentration falls below the threshold, the worker may be unconscious.If you receive a warning email for practical purposes, be sure to notify the manager (the worker). ) directly to confirm their safety.

Figure 6 shows an example of an alarm email sent from the management server 3 to the administrator's communication terminal T, and shows the alarm level of a gas detector (portable gas monitor) used by a certain user (worker). A message is displayed requesting that the safety of the worker be confirmed as a gas has been detected, as well as information on the gas detection location (location information available on the website) and gas warning details (gas type, gas concentration). Gas information such as detection level) is displayed. The content of this warning mail is not limited to that shown in FIG. 6, and can take various forms. Note that the descriptions with frames in FIG. 6 explain the meaning of each display section.
Managers who receive this warning email can call workers to confirm their safety and instruct them to evacuate to a safe location, or if they cannot get through by phone, they can assume that the worker is unconscious and rely on location information. Respond to the situation by going to rescue.

Further, gas information g and position information p for a certain period (for example, about one year) are stored and accumulated in the management server 3 (database unit 32) in association with each other (linkage). Conventionally, past information on gas monitors is not recorded, or even if it is recorded, it is only chronological data, so it is difficult to know where, what kind of gas was detected, and at what frequency and concentration level. could not be quantitatively understood. On the other hand, the management server 3 constituting the present invention accumulates gas information g and position information p in the database section 32, and since this can be viewed, it is possible to know where, what kind of gas, and how often. It is possible to quantitatively understand whether the gas has been detected at the concentration level, and it is therefore possible to identify leak points of toxic gas that require repair (leak points due to aging equipment, etc.).

Furthermore, since gas information g and position information p are accumulated in the management server 3 (database unit 32) as described above, it is possible to search such accumulated past data on a web page. be. FIG. 7 shows an example of the search screen, in which gas information g and position information p for a certain period can be displayed on a map. On this search screen, you can select the data extraction period, gas type (select from "oxygen", "carbon monoxide", "hydrogen sulfide", "flammable gas"), measurement results ("1st level alarm or higher", " If you select ``Second level alarm or higher'' and ``All'', gas information g and location information p for users 1 and 2 during the data extraction period will be displayed on the map on the screen. In Figure 7, "carbon monoxide" is selected as the gas type and "1st level alarm or higher" is selected as the measurement result, so points where 1st level and 2nd level alarms were issued for carbon monoxide during a certain period of time. is displayed as a mark. Each row of detailed information (gas information/location information) shown in the table at the bottom of the screen corresponds one-to-one with multiple marks on the map, and detailed information can be obtained by clicking on each mark on the map. is displayed, so you can use it to check against each row of the table at the bottom of the screen. "Show/Hide" and "Download" in the table in the middle of the screen are each buttons, and "Show/Hide" is a button that allows you to select whether or not to display this user's information on the map. Yes, and can be shown/hidden by clicking. "Download" is a button for downloading this information as a csv file or the like. Note that the search screen is not limited to that shown in FIG. 7, and can take various forms.

In the present invention, by providing one ID for each GPS-equipped mobile terminal, multiple sets of GPS-equipped mobile terminals 2+portable gas monitors 1, that is, a plurality of workers, can be monitored.
As mentioned above, other embodiments of the present invention include [i] enabling gas information g and position information p to be monitored in real time on a web page provided (generated) by the management server 3; [ii] When the management server 3 receives gas information g and position information p in which the gas concentration is at an abnormal value level and requires an alarm to be issued, the management server 3 sends the message to the communication terminal T of the administrator whose e-mail address has been registered in advance. , or send an alarm email with the gas information g and location information p attached.
In addition, regarding the alarm email sent to the administrator's communication terminal T, it may be possible to send an alert email with only one level, or with three levels depending on the gas concentration of gas information g. The above warning mails (for example, 1st stage warning mail, 2nd stage warning mail, 3rd stage warning mail) may be sent.
Examples of gases whose concentration is measured by the gas monitor include oxygen, hydrogen sulfide, and combustible gases in addition to CO exemplified in the above-described embodiment. It can also be applied when the object is to be measured.

1 Portable gas monitor 2 Mobile terminal equipped with GPS 3 Management server 4 Mail server 10 Gas sensor 11 Gas information generation section 12 Display processing section 13 Display section 14 Communication section 20 Near field communication section 21 Information processing section 22 Abnormal data determination section 23 Transmission data generation Section 24 Transmission control section 25 Long distance communication section 26 GPS acquisition section 27a Terminal input section 27b Terminal output section 27c Terminal control section 27d Terminal storage section 28a Touch panel 28b Display 28c Speaker 30 Transmission data determination section 31 Alarm mail generation section 32 Database section 33 Web page generation section 34 Web server section 35 Communication module 320 Gas information database 321 Location information database 330 Gas information management section 331 Location information management section
T, T _X communication terminal
g Gas information
p Location information

Claims (12)

A portable gas monitor (1) is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and combines this with position information (p) acquired by the GPS function. A GPS-equipped mobile terminal (2) that transmits the relevant gas information (g) and its location information (p) to the management server (3) after being associated, and the gas information transmitted from the GPS-equipped mobile terminal (2). (g) and a management server (3) that stores location information (p);
A gas remote monitoring system characterized in that gas information (g) and location information (p) can be monitored in real time on a web page provided by a management server (3). The gas information (g) and location information (p) stored in the management server (3) are displayed on a map of a web page provided by the management server (3). Gas remote monitoring system. A portable gas monitor (1) is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and combines this with position information (p) acquired by the GPS function. A GPS-equipped mobile terminal (2) that transmits the relevant gas information (g) and its location information (p) to the management server (3) after being associated, and the gas information transmitted from the GPS-equipped mobile terminal (2). (g) and a management server (3) that stores location information (p);
When the management server (3) receives gas information (g) and location information (p) in which the gas concentration is at an abnormal level and requires an alarm, the management server (3) sends a message to the administrator whose e-mail address has been registered in advance. A gas remote monitoring system characterized by transmitting an alarm email with gas information (g) and location information (p) attached to a terminal (T). A portable gas monitor (1) is wirelessly connected to the portable gas monitor (1), receives gas information (g) from the portable gas monitor (1), and combines this with position information (p) acquired by the GPS function. A GPS-equipped mobile terminal (2) that transmits the relevant gas information (g) and its location information (p) to the management server (3) after being associated, and the gas information transmitted from the GPS-equipped mobile terminal (2). (g) and a management server (3) that stores location information (p);
In addition to being able to monitor gas information (g) and location information (p) in real time on the web page provided by the management server (3),
When the management server (3) receives gas information (g) and location information (p) in which the gas concentration is at an abnormal level and requires an alarm, the management server (3) sends a message to the administrator whose e-mail address has been registered in advance. A gas remote monitoring system characterized by transmitting an alarm email with gas information (g) and location information (p) attached to a terminal (T). 5. The gas information (g) and location information (p) stored in the management server (3) are displayed on a map of a web page provided by the management server (3). Gas remote monitoring system. A request characterized in that an alarm email with two or more different alarm levels is sent from the management server (3) to the administrator's communication terminal (T) according to the gas concentration of the gas information (g). The gas remote monitoring system according to any one of Items 3 to 5. The gas remote monitoring system according to any one of claims 3 to 6, characterized in that a dead time is provided for sending an alarm email from the management server (3) to the administrator's communication terminal (T). The GPS-equipped mobile terminal (2) constantly transmits gas information (g) and its position information (p) received from the portable gas monitor (1) to the management server (3) in a fixed format, and also detects abnormal gas concentrations. When predetermined gas information (g) at a value level is received from the portable gas monitor (1), the gas information (g) and its position information (p) are immediately transmitted to the management server (3) by interrupt processing. The gas remote monitoring system according to any one of claims 3 to 7, characterized by: The GPS-equipped mobile terminal (2) receives gas information (g) from the portable gas monitor (1) at regular intervals, associates this with the position information (p) acquired by the GPS function, and also Determine whether the gas concentration in (g) is at an abnormal value level, and send the gas information (g) and its location information (p) to the management server (3) according to (i) and (ii) below. Send according to the conditions,
(i) At fixed time intervals, all the gas information (g) and its position information (p) received from the portable gas monitor (1) within the fixed time are collectively transmitted to the management server (3).
(ii) When gas information (g) whose gas concentration is at an abnormal value level and satisfies certain conditions is received from the portable gas monitor (1), the gas information (g) and its position information (p) are It is immediately transmitted to the management server (3) as information requiring an alarm.
When the management server (3) receives the gas information (g) and location information (p) in (ii) above, the management server (3) sends the gas information (g) and location information (p) to the administrator's communication terminal (T). 9. The gas remote monitoring system according to claim 8, wherein the gas remote monitoring system transmits an attached warning email. The GPS-equipped mobile terminal (2) determines whether the gas concentration in the gas information (g) is at an abnormal value level using gas concentration thresholds set in one or more stages, and also determines whether the gas concentration in the gas information (g) is at an abnormal value level. g) and the previously received gas information (g ₀ ), and if the gas information (g) satisfies the conditions (a) and (b) below, the gas information (g) and its location information are (p) is immediately sent to the management server (3) as information requiring an alarm, and if gas information (g) satisfies the conditions (a) and (c) below, it is sent to the previous management server (3). The immediate management server ( 10. The gas remote monitoring system according to claim 9, wherein the gas remote monitoring system transmits to 3).
(a) The gas concentration in gas information (g) is at an abnormal value level.
(b) The abnormal value level of the gas concentration in the gas information (g) is at least one step higher than the abnormal value level of the gas concentration in the previously received gas information (g ₀ ). (Including the case where the gas concentration of _g0 ) is not at an abnormal value level, but the gas concentration of gas information (g) is at an abnormal value level.)
(c) The abnormal value level of the gas concentration in the gas information (g) is the same level as the abnormal value level of the gas concentration in the previously received gas information (g ₀ ), or is at least one step lower. . Gas according to any one of claims 1 to 10, characterized in that the GPS-equipped mobile terminal (2) can selectively wirelessly connect with portable gas monitors (1) from multiple manufacturers using one application. Remote monitoring system. Using the gas remote monitoring system according to any one of claims 1 to 11, the leak location of harmful gas in the equipment is determined based on the gas information (g) and position information (p) stored in the management server (3). A method for identifying a hazardous gas leak location, the method comprising: identifying a hazardous gas leak location;

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