CN211236661U - Monitoring system - Google Patents

Abstract

The application discloses monitoring system belongs to gas transmission station management field. The monitoring system includes: the system comprises one or more data acquisition devices, one or more control hosts and a data centralized management device, wherein the one or more data acquisition devices correspond to the one or more control hosts one to one; the data acquisition end of each data acquisition device is used for being electrically connected with a corresponding uninterrupted power supply UPS, the data output end of each data acquisition device is electrically connected with a corresponding control host, and one or more control hosts are in communication connection with the data centralized management device. The monitoring system provided by the application can directly check the running conditions of the UPSs in different areas in real time at the data centralized management equipment, and the condition that technicians need to observe the running conditions of the UPSs in different areas in real time is avoided, so that the labor intensity of the technicians is reduced, and the management difficulty of each UPS is reduced.

Description

Monitoring system

Technical Field

The application relates to the field of gas transmission station management, in particular to a monitoring system.

Background

In order to ensure the normal operation of each electric device in the gas transmission station and avoid the problem of data loss of each electric device due to the power failure of the utility power, a UPS (uninterruptible power supply) is usually installed in each gas transmission station, wherein the UPS is connected to each electric device. Therefore, the UPS can be started to supply power to each electric device under the condition of mains supply power failure, so that the problems of data loss and the like of the electric devices are avoided. It can be seen that the normal operation of the UPS is critical to the normal operation of the entire gas transmission yard.

In order to ensure the normal operation of the UPS, technicians are required to observe the operation condition of the UPS in real time at each gas transmission station, which not only increases the labor intensity of the technicians, but also increases the management difficulty due to the fact that the distribution of each gas transmission station is relatively dispersed.

SUMMERY OF THE UTILITY MODEL

The application provides a monitoring system, can solve technical staff intensity of labour big and to the big problem of each UPS management degree of difficulty. The technical scheme is as follows:

there is provided a monitoring system, the monitoring system comprising: the system comprises one or more data acquisition devices, one or more control hosts and a data centralized management device, wherein the one or more data acquisition devices correspond to the one or more control hosts one to one;

the data acquisition end of each data acquisition equipment is used for being connected with a corresponding uninterrupted power supply UPS electricity, and the data output end of each data acquisition equipment is connected with a corresponding control host electricity, one or more control hosts all with data centralized management equipment communication is connected, one or more control hosts can with received data transmission extremely data centralized management equipment, every data acquisition equipment all is located same gas transmission station with corresponding UPS, corresponding control host.

Optionally, the monitoring system further comprises: one or more temperature sensors;

the one or more temperature sensors are in one-to-one correspondence with the one or more control hosts, each temperature sensor is electrically connected with one corresponding control host, and each temperature sensor is used for detecting the temperature of the environment where one corresponding UPS is located.

Optionally, the monitoring system further comprises: one or more remote discharge meters;

the one or more remote discharge instruments are in one-to-one correspondence with the one or more control hosts, a signal input end of each remote discharge instrument is electrically connected with one corresponding control host, a signal output end of each remote discharge instrument is used for being electrically connected with one corresponding UPS, and each remote discharge instrument can control one corresponding UPS to discharge based on a control signal transmitted by one corresponding control host.

Optionally, each data acquisition device comprises a voltage detector and a current detector;

the voltage detector and the current detector are electrically connected with the UPS, the voltage detector is used for detecting the supply voltage of the UPS, and the current detector is used for detecting the supply current of the UPS.

Optionally, the monitoring system further comprises: a first alarm;

the first alarm is electrically connected with the data centralized management equipment, and the first alarm can give an alarm when the data received by the data centralized management equipment do not meet preset conditions.

Optionally, the first alarm comprises a sound emitting module and/or a light emitting module.

Optionally, the monitoring system further comprises a maintenance terminal;

the maintenance terminal is electrically connected with the data centralized management equipment and used for receiving alarm information transmitted by the data centralized management equipment, and the alarm information is generated by the data centralized management equipment based on data which do not meet preset conditions.

Optionally, each control host is provided with a network adapter.

Optionally, the monitoring system further comprises: one or more humidity sensors;

the one or more humidity sensors are in one-to-one correspondence with the one or more control hosts, each humidity sensor is electrically connected with one corresponding control host, and each humidity sensor is used for detecting the humidity of the environment where the corresponding UPS is located.

Optionally, the monitoring system further comprises: one or more second alarms which correspond to the one or more control hosts one to one;

each second alarm is electrically connected with the corresponding control host, and each second alarm can give an alarm when the data received by the corresponding control host do not meet the preset conditions.

The beneficial effects that technical scheme that this application provided brought can include at least:

in the embodiment of the application, each data acquisition device can acquire the operation data of the corresponding UPS and send the acquired operation data to the corresponding control host, and then the corresponding control host can send the operation data to the data centralized management device. Since the UPSs are usually distributed in different gas transmission sites, the operation data of the UPSs in the different gas transmission sites can be centrally managed by the data centralized management device after being sent to the data centralized management device. In other words, the operation data of the UPSs in different gas transmission stations can be checked through the data centralized management equipment, and the operation conditions of the UPSs in different gas transmission stations can be further known. That is, the monitoring system that this application embodiment provided can directly look over the operational aspect of UPS in different gas transmission station yards in real time through data centralized management equipment, has avoided the emergence that needs the operating aspect of technical staff real-time observation UPS in each different gas transmission station yard, therefore will reduce technical staff's intensity of labour, will also reduce the management degree of difficulty to each UPS.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a monitoring system according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a data acquisition device according to an embodiment of the present application;

FIG. 3 is a schematic structural diagram of another monitoring system provided in the embodiments of the present application;

fig. 4 is a schematic structural diagram of another monitoring system provided in an embodiment of the present application.

Reference numerals:

1: a data acquisition device; 2: a control host; 3: a data centralized management device; 4: a temperature sensor; 5: a remote discharge instrument; 6: a first alarm; 7: maintaining the terminal; 8: a humidity sensor; 9: a second alarm;

11: a voltage detector; 12: a current detector;

100：UPS。

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a monitoring system according to an embodiment of the present application. Referring to fig. 1, the monitoring system may include: the system comprises one or more data acquisition devices 1, one or more control hosts 2 and a data centralized management device 3, wherein the one or more data acquisition devices 1 correspond to the one or more control hosts 2 one to one. The data acquisition end of each data acquisition device 1 is used for being electrically connected with a corresponding UPS100, the data output end of each data acquisition device 1 is electrically connected with a corresponding control host 2, one or more control hosts 2 are in communication connection with a data centralized management device 3, the one or more control hosts 2 can transmit received data to the data centralized management device 3, and each data acquisition device 1, the corresponding UPS100 and the corresponding control host 2 are located in the same gas transmission station.

In this embodiment, each data collection device 1 may collect operation data of the corresponding UPS100, and send the collected operation data to the corresponding control host 2, and then the corresponding control host 2 may send the operation data to the data centralized management device 3. Since the UPSs 100 are generally distributed in different gas transmission sites, the operation data of the UPSs 100 in the different gas transmission sites can be centrally managed by the data centralized management apparatus 3 after being transmitted to the data centralized management apparatus 3. In other words, the operation data of the UPS100 in different gas transmission sites can be viewed by the data centralized management device 3, and the operation conditions of the UPS100 in different gas transmission sites can be known. That is, the monitoring system provided in the embodiment of the present application can directly check the operation conditions of the UPS100 in different gas transmission stations through the data centralized management device 3 in real time, and avoids the occurrence that technicians need to observe the operation conditions of the UPS100 in real time in different gas transmission stations, so that the labor intensity of the technicians is reduced, and the management difficulty of each UPS100 is also reduced.

The operation data of the UPS100 in different gas transmission sites viewed in real time by the data centralized management device 3 is only an application scenario of a possible monitoring system shown in the embodiment of the present application, and of course, the monitoring system may also be applied in other scenarios, for example, the monitoring system may also be used to view operation conditions of the UPSs in different oil transmission sites in real time, and the application scenario of the monitoring system is not specifically limited in the embodiment of the present application.

For ease of understanding, the data centralized management device 3 may be understood as a background monitoring center. Of course, based on different application scenarios, the data centralized management device 3 may also be understood as other devices, which is not specifically limited in this embodiment of the application.

It should be noted that the operation condition of the UPS100 can be determined by monitoring the operation data of the UPS100, such as the power supply voltage and the power supply current of the UPS100 in real time, and at this time, referring to fig. 2, each data acquisition device 1 may include a voltage detector 11 and a current detector 12. A voltage detector 11 and a current detector 12 are electrically connected to the UPS100, the voltage detector 11 being configured to detect a supply voltage of the UPS100, and the current detector 12 being configured to detect a supply current of the UPS 100. In this way, the power supply voltage and the power supply current of the corresponding UPS100 can be collected by each data collection device 1, and the operation condition of the UPS100 is determined according to the collected power supply voltage and power supply current. Of course, each data collection device 1 may further include other components based on different usage requirements, and may also be used to collect other operation data of the UPS100, which is not specifically limited in this embodiment of the application.

In some embodiments, each control host 2 may be a computer device. Of course, the control host 2 may also be other devices, and only the received data needs to be transmitted to the data centralized management device 3, and the embodiment of the present application does not specifically limit the control host 2.

In some embodiments, each control host 2 may be provided with a network adapter. When the control hosts 2 are provided with the network adapters, in some scenarios, each control host 2 can access a LAN/WAN network or an Internet network, and transmit the operation data of the UPS100 to a related website through the LAN/WAN network or the Internet network, so that a technician can access the related website through a browser and check the operation condition of the UPS100 on the related website, thereby facilitating monitoring of the UPS 100.

Next, the working process of the monitoring system will be described in detail by way of example in the embodiments of the present application.

Firstly, assuming that a first gas transmission station yard is arranged at a site, a second gas transmission station yard is arranged at a site B, and a data centralized management device 3 is arranged at a site C, it is continuously assumed that a first UPS100 is arranged in the first gas transmission station yard, and a first control host and a first data acquisition device corresponding to the first UPS are simultaneously arranged, and a second UPS is arranged in the second gas transmission station yard, and a second control host and a second data acquisition device corresponding to the second UPS are simultaneously arranged. Then, the first data collection device may collect operation data of the first UPS located at the a site, and send the collected operation data to the first control host, and the first control host may send the operation data to the data centralized management device 3 located at the C site after receiving the operation data, that is, may view the operation condition of the first UPS located at the a site at the C site. Similarly, the second data collection device may collect operation data of the second UPS located at the location B, and send the collected operation data to the second control host, and the second control host may send the operation data to the data centralized management device located at the location C after receiving the operation data, that is, may check the operation condition of the second UPS located at the location B at the location C. In summary, the operating condition of the first UPS located at the a site and the operating condition of the second UPS located at the B site can be checked at the C site, so that a situation that technicians need to be arranged at both the a site and the B site is avoided, the labor intensity of the technicians can be obviously reduced, and the management difficulty of the first UPS and the second UPS can be reduced.

In the operation process of the UPS100, the temperature of the environment where the UPS100 is located can also reflect the operation condition of the UPS100, for example, in some embodiments, when the temperature of the environment where the UPS100 is located sharply increases, it may be preliminarily determined that an abnormality occurs in the operation of the UPS100, and therefore, monitoring the temperature of the environment where the UPS100 is located in real time is also important for determining the operation condition of the UPS 100. Based on this, referring to fig. 3, in some embodiments, the monitoring system may further comprise: one or more temperature sensors 4; one or more temperature sensors 4 are in one-to-one correspondence with one or more control hosts 2, each temperature sensor 4 is electrically connected with a corresponding one of the control hosts 2, and each temperature sensor 4 is configured to detect a temperature of an environment in which a corresponding one of the UPSs 100 is located. Therefore, the temperature of the environment where the UPS100 is located can be monitored in real time through the temperature sensor 4, the running condition of the UPS100 is further judged according to the temperature of the environment where the UPS100 is located, and technicians can timely process the environment where the UPS100 is located when the temperature of the environment does not accord with preset conditions.

During the operation of the UPS100, it is also necessary to monitor the humidity of the environment where the UPS100 is located in real time, and when the humidity of the environment where the UPS100 is located does not meet the preset condition, the normal operation of the UPS100 may be affected, for example, when the humidity of the environment where the UPS100 is located is too high, the normal operation of the UPS100 may be affected, based on this, in some embodiments, referring to fig. 4, the monitoring system may further include: one or more humidity sensors 8. One or more humidity sensors 8 correspond to one or more control hosts 2 one to one, each humidity sensor 8 is electrically connected to a corresponding control host 2, and each humidity sensor 8 is configured to detect humidity of an environment where a corresponding UPS100 is located. Therefore, the humidity of the environment where the UPS100 is located can be monitored in real time through the humidity sensor 8, and the environment humidity is timely processed when being not consistent with the preset condition, so that the influence of the environment humidity on the normal operation of the UPS100 is avoided.

In addition, in order to ensure the normal operation of the UPS100, the UPS100 needs to be discharged at certain intervals. For example, in some embodiments, the UPS100 may be discharged once a month apart, and based on this, in some embodiments, referring to fig. 4, the monitoring system may further include: one or more remote dischargers 5. One or more remote discharge instruments 5 are in one-to-one correspondence with one or more control hosts 2, a signal input end of each remote discharge instrument 5 is electrically connected with a corresponding one of the control hosts 2, a signal output end of each remote discharge instrument 5 is used for being electrically connected with a corresponding one of the UPSs 100, and each remote discharge instrument 5 can control the corresponding one of the UPSs 100 to discharge based on a control signal transmitted by the corresponding one of the control hosts 2. Thus, the discharge of the UPS100 in different areas can be controlled directly by the data centralized management apparatus 3.

For example, a first UPS located at a location a needs to be discharged once, and if the first UPS corresponds to a first remote discharge apparatus, in a possible implementation manner, a first signal may be transmitted to the first control host through the data centralized management device 3, after the first control host receives the first signal, a second signal may be transmitted to the first remote discharge apparatus, and after the first remote discharge apparatus receives the second signal, the first UPS may be controlled to discharge based on the second signal, that is, discharging of the first UPS is implemented.

In summary, after the data centralized management apparatus 3 receives the operation data of the UPSs 100 of the different areas, the operation condition of the UPSs 100 can be determined based on the operation data of the UPSs 100. For example, assuming that the environment temperature of the UPS100 is abnormal when the environment temperature of the UPS100 is above 40 degrees celsius, the data centralized management device 3 continues to include a display device, and in one scenario, the display device may display the temperatures of the UPS100 in different areas, and at this time, assuming that a technician sees the environment temperature of the first UPS100 located at the a site as 50 degrees celsius through the display device, that the first UPS100 is considered to be abnormal in operation, then the technician may go to a to process the abnormality immediately.

As can be seen from the above description, although the above embodiments do not require technicians to monitor the operation data of the UPSs 100 in different areas in different gas transmission station yards, the technicians still need to monitor the operation data of the UPSs 100 in different areas in real time through the data centralized management device 3, which makes the technicians still labor-intensive. Based on this, further, referring to fig. 4, the monitoring system may further include: a first alarm 6. The first alarm 6 is electrically connected with the data centralized management device 3, and the first alarm 6 can give an alarm when the data received by the data centralized management device 3 does not meet the preset conditions. Thus, continuing with the above embodiment, assuming that the ambient temperature of the first UPS100 received by the data centralized management apparatus 3 is 50 degrees celsius and the preset condition is that the ambient temperature is not greater than 40 degrees celsius, at this time, it is seen that the ambient temperature does not meet the preset condition, then the alarm may be given through the first alarm 6, where the first alarm 6 may include a sound module and/or a light module. In this way, the technician can go to a to handle the anomaly after hearing the sound emitted by the first alarm 6 and/or seeing the light emitted by the first alarm 6 at the data set management device. This will avoid the need for a technician to monitor the operational data of the UPS100 in different gas transmission sites via the data centralized management apparatus 3 in real time, further reducing the labor intensity of the technician.

Further, in other embodiments, referring to fig. 4, the monitoring system may further include: one or more second alarm devices 9, one or more second alarm devices 9 and one or more control host computers 2 correspond to each other one by one. Each second alarm 9 is electrically connected with the corresponding control host 2, and each second alarm 9 can give an alarm when the data received by the corresponding control host 2 does not meet the preset condition. Thus, if the operational data of the first UPS100 at the a site does not meet the preset conditions, the alarm can be given directly at the a site where the first UPS100 is located by the second alarm 9, and the technician can deal with the abnormality directly at the a site after hearing the sound given by the second alarm 9 and/or seeing the light given by the second alarm 9.

Further, in some embodiments, referring to fig. 4, the monitoring system further comprises a maintenance terminal 7. The maintenance terminal 7 is electrically connected with the data centralized management device 3, the maintenance terminal 7 is used for receiving alarm information transmitted by the data centralized management device 3, and the alarm information refers to information generated by the data centralized management device 3 based on data which do not meet preset conditions. In this way, in some scenarios, after receiving the alarm information transmitted by the centralized data management device 3, the maintenance terminal 7 may directly display the alarm information on the maintenance terminal 7, so that a technician may directly view the operation condition of the UPS100 on the maintenance terminal 7, which is more convenient than viewing the operation condition of the UPS100 through the centralized data management device 3.

The maintenance terminals may correspond to the UPSs one by one, that is, one maintenance terminal 7 corresponds to one UPS100, and of course, based on different scenarios, the number of the maintenance terminals 7 may also be unequal to the number of the UPSs 100, for example, for some UPSs 100 that need to be monitored intensively, 2 maintenance terminals 7 may also correspond to one UPS100, which is not specifically limited in the embodiment of the present application.

In this embodiment, each data collection device 1 may collect operation data of the corresponding UPS100, and send the collected operation data to the corresponding control host 2, and then the corresponding control host 2 may send the operation data to the data centralized management device 3. Since the UPSs 100 are generally distributed in different gas transmission sites, the operation data of the UPSs 100 in the different gas transmission sites can be centrally managed by the data centralized management apparatus 3 after being transmitted to the data centralized management apparatus 3. In other words, the operation data of the UPS100 in different gas transmission sites can be viewed by the data centralized management device 3, and the operation conditions of the UPS100 in different gas transmission sites can be known. That is, the monitoring system provided in the embodiment of the present application can directly check the operation conditions of the UPS100 in different gas transmission stations through the data centralized management device 3 in real time, and avoids the occurrence that technicians need to observe the operation conditions of the UPS100 in real time in different gas transmission stations, so that the labor intensity of the technicians is reduced, and the management difficulty of each UPS100 is also reduced.

In addition, the monitoring system may also include one or more remote discharge meters 5. Each of the remote discharging apparatuses 5 is capable of controlling the discharge of a corresponding one of the UPSs 100 based on a control signal transmitted from a corresponding one of the control hosts 2. That is, the monitoring system provided in the embodiment of the present application can not only monitor the operation conditions of the UPSs in different areas at the data centralized management device 3, but also directly implement remote management of the UPSs 100 in different areas at the data centralized management device 3 through the remote discharging instrument 5, thereby further reducing the labor intensity of technicians and further reducing the management difficulty of the UPSs in different areas.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A monitoring system, characterized in that the monitoring system comprises: the system comprises one or more data acquisition devices (1), one or more control hosts (2) and a data centralized management device (3), wherein the one or more data acquisition devices (1) correspond to the one or more control hosts (2) one by one;

the data acquisition end of every data acquisition equipment (1) is used for being connected with a corresponding uninterrupted power source UPS (100) electricity, and the data output end of every data acquisition equipment (1) is connected with a control host (2) electricity that corresponds, one or more control host (2) all with data centralized management equipment (3) communication is connected, one or more control host (2) can with received data transmission extremely data centralized management equipment (3), every data acquisition equipment (1) and corresponding UPS (100), corresponding control host (2) all are located same gas transmission station field.

2. The monitoring system of claim 1, further comprising: one or more temperature sensors (4);

the one or more temperature sensors (4) are in one-to-one correspondence with the one or more control hosts (2), each temperature sensor (4) is electrically connected with one corresponding control host (2), and each temperature sensor (4) is used for detecting the temperature of the environment where one corresponding UPS (100) is located.

3. The monitoring system of claim 1, further comprising: one or more remote dischargers (5);

the one or more remote discharge instruments (5) are in one-to-one correspondence with the one or more control hosts (2), the signal input end of each remote discharge instrument (5) is electrically connected with the corresponding one of the control hosts (2), the signal output end of each remote discharge instrument (5) is electrically connected with the corresponding one of the UPSs (100), and each remote discharge instrument (5) can control the corresponding one of the UPSs (100) to discharge based on the control signal transmitted by the corresponding one of the control hosts (2).

4. A monitoring system according to any of claims 1-3, characterized in that each data acquisition device (1) comprises a voltage detector (11) and a current detector (12);

the voltage detector (11) and the current detector (12) are electrically connected to the UPS (100), the voltage detector (11) is used for detecting the supply voltage of the UPS (100), and the current detector (12) is used for detecting the supply current of the UPS (100).

5. The monitoring system of claim 1, further comprising: a first alarm (6);

the first alarm (6) is electrically connected with the data centralized management equipment (3), and the first alarm (6) can give an alarm when the data received by the data centralized management equipment (3) do not meet preset conditions.

6. A monitoring system according to claim 5, wherein the first alarm (6) comprises a sound emitting module and/or a light emitting module.

7. The monitoring system according to claim 1 or 5, characterized in that it further comprises a maintenance terminal (7);

the maintenance terminal (7) is electrically connected with the data centralized management device (3), the maintenance terminal (7) is used for receiving alarm information transmitted by the data centralized management device (3), and the alarm information is generated by the data centralized management device (3) based on data which do not meet preset conditions.

8. A monitoring system according to claim 1, characterized in that each control host (2) is provided with a network adapter.

9. The monitoring system of claim 1, further comprising: one or more humidity sensors (8);

the one or more humidity sensors (8) are in one-to-one correspondence with the one or more control hosts (2), each humidity sensor (8) is electrically connected with one corresponding control host (2), and each humidity sensor (8) is used for detecting the humidity of the environment where one corresponding UPS (100) is located.

10. The monitoring system of claim 1, further comprising: one or more second alarms (9), wherein the one or more second alarms (9) correspond to the one or more control hosts (2) one by one;

each second alarm (9) is electrically connected with the corresponding control host (2), and each second alarm (9) can give an alarm when the data received by the corresponding control host (2) does not meet the preset condition.

Images