CN213959828U - Low-voltage power distribution system based on oil sludge treatment station - Google Patents

Abstract

The embodiment of the application discloses low pressure distribution system based on sludge treatment station for solve among the prior art and carry out the lower, the higher problem of potential safety hazard of intelligent degree of distribution management to sludge treatment station. The system comprises a low-voltage power distribution module, a comprehensive management platform and a workshop production module which are connected with each other; the low-voltage power distribution module comprises a first data processing device, a high-voltage power distribution device and a low-voltage power distribution device which are connected with each other; a transformer is connected between the high-voltage distribution device and the low-voltage distribution device; the workshop production module comprises production equipment and a second data processing device which are connected with each other; the comprehensive management platform comprises at least two data analysis devices, and each data analysis device is connected with the first data processing device and the second data processing device respectively. The low-voltage power distribution system achieves the effect of intelligently carrying out low-voltage power distribution on the oil sludge treatment station, and improves the power utilization safety of the oil sludge treatment station.

Description

Low-voltage power distribution system based on oil sludge treatment station

Technical Field

The application relates to the technical field of power distribution, in particular to a low-voltage power distribution system based on an oil sludge treatment station.

Background

In the field of oily waste treatment, because the treatment process is complex, more equipment is caused, the power of the set of process equipment is higher, and the energy consumption is higher, the power management of each equipment becomes the industry requirement.

The existing power utilization management mode needs a large amount of manual participation, and the intelligent degree is low. Because the equipment that handles oily waste is in explosion-proof region, when opening equipment and handling oily waste, to the power consumption control and the management of equipment, can bring different security threats for staff and equipment self to the flow that stops to equipment power supply is complicated, has not only promoted staff's work load, and the potential safety hazard is also higher moreover.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application aims to provide a low-voltage power distribution system based on an oil sludge treatment station, and aims to solve the problems that in the prior art, the intelligent degree of power distribution management of the oil sludge treatment station is low and potential safety hazards are high.

In order to solve the above technical problem, the embodiment of the present application is implemented as follows:

the embodiment of the application provides a low-voltage power distribution system based on an oil sludge treatment station, which comprises a low-voltage power distribution module, a comprehensive management platform and a workshop production module which are connected with one another; wherein the content of the first and second substances,

the low-voltage power distribution module comprises a first data processing device, a high-voltage power distribution device and a low-voltage power distribution device which are connected with each other; a transformer is connected between the high-voltage distribution device and the low-voltage distribution device;

the workshop production module comprises production equipment and a second data processing device which are connected with each other;

the integrated management platform comprises at least two data analysis devices, and each data analysis device is connected with the first data processing device and the second data processing device respectively.

The low-voltage power distribution system based on the oil sludge treatment station comprises a low-voltage power distribution module, a comprehensive management platform and a workshop production module which are connected with one another. Because the low-voltage distribution module includes interconnect's first data processing device, high-voltage distribution device and low-voltage distribution device, be connected with the transformer between high-voltage distribution device and the low-voltage distribution device, workshop production module includes interconnect's production facility and second data processing device, and the integrated management platform includes two at least data analysis equipment, and each data analysis equipment is connected with first data processing device and second data processing device respectively. Therefore, the low-voltage power distribution system can achieve the effect of analyzing the data of production equipment, a high-voltage power distribution device and a low-voltage power distribution device in the comprehensive management platform, so that the purpose of controlling the power supply condition between the low-voltage power distribution module and the workshop production module through the comprehensive management platform is achieved, the effect of intelligently conducting low-voltage power distribution on the oil sludge treatment station is achieved, and the power utilization safety of the oil sludge treatment station is improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only some embodiments described in the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without any creative effort.

Fig. 1 is a schematic block diagram of a low voltage power distribution system based on a sludge treatment plant according to an embodiment of the present application;

fig. 2 is a schematic block diagram of a low voltage power distribution system based on a sludge treatment plant according to another embodiment of the present application.

Detailed Description

The embodiment of the application provides a low voltage distribution based on sludge treatment station for solve among the prior art and carry out the problem that intelligent degree is lower, the potential safety hazard is higher that the distribution was managed to sludge treatment station.

In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Fig. 1 is a schematic block diagram of a low-voltage power distribution system based on an oil sludge treatment station according to an embodiment of the present application, and the system includes a low-voltage power distribution module, an integrated management platform and a workshop production module which are connected with each other, as shown in fig. 1; wherein the content of the first and second substances,

the low-voltage distribution module comprises a first data processing device 10, a high-voltage distribution device 11 and a low-voltage distribution device 12 which are connected with each other, and a transformer 13 is connected between the high-voltage distribution device 11 and the low-voltage distribution device 12. The shop production module comprises a production device 20 and a second data processing means 21 connected to each other. The integrated management platform comprises at least two data analysis devices 30 (only two data analysis devices 30 are schematically shown in fig. 1), and each data analysis device 30 is connected with the first data processing apparatus 10 and the second data processing apparatus 21 respectively.

Wherein the mains supply is connected to the high voltage distribution device 11, the low voltage distribution device 12 is electrically connected to the production equipment 20 (the above connection relation is not shown in fig. 1), and the transformer 13 is used for transforming the high voltage of 10 kv to 220 kv provided by the mains supply into the low voltage of 220 v to 380 v required by the production equipment 20, and transmitting the low voltage to the production equipment 20 via the low voltage distribution device 12.

In one embodiment, the high voltage power distribution device 11 includes a first switch and a first circuit breaker therein, and the low voltage power distribution device 12 includes a second switch and a second circuit breaker therein. The first switch, the first breaker, the second switch, and the second breaker are respectively connected to the first data processing apparatus 10 (the structure and connection relationship described in this embodiment are not shown in fig. 1). In addition, the high-voltage distribution device 11 and the low-voltage distribution device 12 respectively include monitoring points such as current, voltage, electric quantity, temperature, humidity, and the like, and related monitoring devices are arranged at the monitoring points, and are connected with the first data processing device 10, so that the first data processing device 10 can receive operation data monitored by the monitoring devices. The related monitoring devices arranged at the monitoring points can be related monitoring instruments, meters, sensors and the like. For example, the monitoring devices arranged at the current and voltage monitoring points are an ammeter and a voltmeter respectively, the monitoring devices arranged at the electric quantity monitoring points are an ammeter, and the monitoring devices arranged at the temperature and humidity monitoring points are a temperature sensor and a humidity sensor respectively.

It should be noted that, in the low-voltage distribution system based on the sludge treatment station provided in the embodiment of the present application, a plurality of low-voltage distribution devices 12 may be included, and each low-voltage distribution device 12 may include a plurality of second switches and a plurality of second breakers. A second switch and a second circuit breaker may control a supply circuit. At this time, by encoding each low-voltage power distribution apparatus 12 and each power supply circuit, each operation data received in the data analysis device 30 can be made to correspond to each power supply circuit in each low-voltage power distribution apparatus 12, thereby realizing targeted control of each power supply circuit.

In the above embodiment, the first data processing device 10 is configured to collect first operation data of the high-voltage power distribution device 11 and the low-voltage power distribution device 12, the second data processing device 21 is configured to collect second operation data of the production equipment 20, and each data analysis device 30 is connected to the first data processing device 10 and the second data processing device 21 through an optical fiber, and can respectively obtain the first operation data and the second operation data, so that each operation data can be analyzed, and the operation of the low-voltage power distribution device 12 is controlled according to an analysis result.

The first operation data may include parameters such as a switch state of a first switch and an on-off state of a first circuit breaker in the high-voltage power distribution device 11, a current, a voltage, an electric quantity, a temperature, and a humidity on the power supply loop, and parameters such as a switch state of a second switch and an on-off state of a second circuit breaker in the low-voltage power distribution device 12, a current, a voltage, an electric quantity, a temperature, and a humidity on the power supply loop. The second operational data may include parameters such as the on or off status of the production equipment 20, the current, voltage, temperature, humidity of the production equipment, and the like.

In this embodiment, the data analysis device receives data of the electricity meter in the high-voltage power distribution device through the first data processing device, can acquire peak and valley electricity consumption data in the low-voltage power distribution system, and receives working state data of each second switch or each second circuit breaker through the first data processing device, and can count the commissioning condition of each power supply loop in the peak and valley electricity consumption period, so that the running time of the production device connected with power supply of each power supply loop in the peak and valley electricity consumption period can be calculated according to the starting commissioning and ending commissioning time of each power supply loop. The method is favorable for analyzing the operation condition of each production device according to the peak-valley period of power utilization, optimizes the operation of the production devices in each period by combining the electricity price of each time period of the peak-valley period of power utilization, and realizes a production mode with low energy consumption, low cost and high efficiency.

In one embodiment, the high voltage distribution device 11 may be a high voltage distribution cabinet and the low voltage distribution device 12 may be a low voltage distribution cabinet. The second switch may be a switch with remote operation capability, such as a stored energy switch. The production facility 20 may include a plurality of facilities, for example, the production facility 20 may include a sludge treatment facility, a process auxiliary facility, and the like. In order to improve the stability of data transmission, each data analysis device 30 may be connected to the first data processing apparatus 10 and the second data processing apparatus 21 through an optical fiber.

In one embodiment, the first data processing apparatus 10 and the second data processing apparatus 21 may be distributed input/output modules, respectively. The distributed input/output module has the characteristics of high reliability, low price, easy setting, convenient network wiring, suitability for application in a scattered area and the like, so that the collection and operation control of the operation data of the high-voltage distribution device 11, the low-voltage distribution device 12 and the production equipment 20 are realized through the distributed input/output module, the distribution efficiency can be improved, and the cost is saved. In addition, the second data processing device 21 may also be an instrument, a meter, etc. which is provided in the production facility 20 and monitors the operation data thereof.

In the low voltage distribution system based on sludge treatment station that this application embodiment provided, because low voltage distribution module includes interconnect's first data processing apparatus, high voltage distribution device and low voltage distribution device, be connected with the transformer between high voltage distribution device and the low voltage distribution device, workshop production module includes interconnect's production facility and second data processing apparatus, the integrated management platform includes two at least data analysis equipment, each data analysis equipment is connected with first data processing apparatus and second data processing apparatus respectively. Therefore, the scheme can realize the effect of analyzing the data of the production equipment, the high-voltage distribution device and the low-voltage distribution device in the comprehensive management platform, thereby achieving the purpose of controlling the power supply condition between the low-voltage distribution module and the workshop production module by the comprehensive management platform, realizing the effect of intelligently performing low-voltage power distribution on the oil sludge treatment station, and improving the power utilization safety of the oil sludge treatment station.

Fig. 2 is a schematic block diagram of a low-voltage power distribution system based on a sludge treatment station according to another embodiment of the present application, and the system includes a low-voltage power distribution module, an integrated management platform and a workshop production module which are connected with each other, as shown in fig. 2. The dashed lines with arrows in fig. 2 indicate the power supply connection direction, and the solid lines with arrows indicate the data flow direction between the components.

The low-voltage power distribution module comprises a first data processing device 10, a high-voltage power distribution device 11 and a low-voltage power distribution device 12 which are connected with each other. A transformer 13 is connected between the high-voltage distribution device 11 and the low-voltage distribution device 12. The shop production module comprises a production device 20 and a second data processing means 21 connected to each other. The integrated management platform comprises at least two data analysis devices 30 (only two data analysis devices 30 are schematically shown in fig. 2), and each data analysis device 30 is connected with the first data processing apparatus 10 and the second data processing apparatus 21 respectively.

The commercial power 40 is electrically connected to the high-voltage distribution device 11, and the low-voltage distribution device 12 is electrically connected to the production equipment 20.

In this embodiment, the functions of the components and the data flow between the components are described in detail in the above embodiments, and are not described again here.

The components and connections of the components of the low voltage distribution system based on the sludge treatment plant are explained in detail below.

In one embodiment, the high voltage power distribution device 11 includes a first switch and a first circuit breaker therein, and the low voltage power distribution device 12 includes a second switch and a second circuit breaker therein. The first switch, the first breaker, the second switch, and the second breaker are connected to the first data processing device 10, respectively (the connection relationship is not shown in fig. 2).

In this embodiment, when the high-voltage power distribution device and the low-voltage power distribution device operate, the first data processing device may acquire the operating states of the first switch, the first circuit breaker, the second switch, and the second circuit breaker. The working state of the switch can be an opening state or a closing state, and the working state of the breaker can be a connection state or a disconnection state.

In one embodiment, the data analysis device 30 may be a lower computer. The integrated management platform may include an upper computer 31 connected to the lower computer (fig. 2 only schematically shows that the upper computer 31 is connected to two data analysis devices 30, respectively).

In this embodiment, the lower computer can be in response to the instruction issued by the upper computer, and archive and analyze the first operation data and the second operation data obtained by the first data processing device and the second data processing device, and send the instruction issued by the upper computer to the first data processing device and the second data processing device, so that the first data processing device and the second data processing device execute corresponding control operations based on the received instruction respectively.

For example, the lower computer can respond to an instruction for balanced load distribution issued by the upper computer, and archive the voltage, the current and the working state of the second switch in the low-voltage distribution device in the first operation data, if the voltage and the current are obtained through analysis and are greatly fluctuated, the lower computer further analyzes which second switch is started to cause fluctuation, the second switch which is obtained through analysis and causes fluctuation is sent to the upper computer, and receives the instruction for disconnecting the second switch issued by the upper computer, and sends the instruction to the first data processing device, so that the first data processing device disconnects the second switch in response to the instruction, thereby reducing the occurrence of harmonic wave and three-phase imbalance conditions, reducing the influence on the service life of production equipment for power supply connection of a loop where the second switch is located, and reducing energy consumption. Meanwhile, the whole process does not need manual participation, and the risk of local operation of workers is reduced.

As shown in fig. 2, the integrated management platform includes a data acquisition device 32, the low voltage power distribution module includes a first monitoring device 14, and the shop production module includes a second monitoring device 22. The data acquisition device 32 is connected to the first monitoring apparatus 14, the second monitoring apparatus 22, and the upper computer 31, respectively.

Wherein the second monitoring device 22 may be an explosion-proof camera. For example, the second monitoring device is an explosion-proof pan-tilt camera. Because the camera shooting range of the pan-tilt camera is wider, and the second monitoring device is arranged in the workshop production module in the explosion-proof area, the explosion-proof pan-tilt camera is used as the second monitoring device, the accuracy of monitoring data can be ensured, the possibility that the second monitoring device is damaged due to the influence of the environment is reduced, and the monitoring cost can be saved.

The data acquisition equipment can be in wireless connection or wired connection with the first monitoring device and the second monitoring device respectively, and the first monitoring device and the second monitoring device can transmit respective monitoring data to the data acquisition equipment in a wireless transmission or wired transmission mode. The data acquisition equipment can be communicated with the upper computer through RS485, so that the monitoring data acquired from the first monitoring device and the second monitoring device are sent to the upper computer.

The upper computer can comprehensively analyze the monitoring data, the first operation data of the low-voltage power distribution module and the second operation data of the workshop production module, which are acquired by the lower computer. For example, whether the operating state of the second switch in the first operation data corresponds to the on or off state of the production equipment in the second operation data is analyzed.

As shown in fig. 2, the integrated management platform includes an abnormality alarm module 33. The abnormality alarm module 33 is connected to the upper computer and the at least two data analysis devices 30, respectively (fig. 2 only schematically shows that the abnormality alarm module 33 is connected to the two data analysis devices 30, respectively).

In this embodiment, the anomaly alarm module may receive an anomaly alarm request sent by each data analysis device when the data is analyzed to be abnormal, and perform anomaly alarm in response to the anomaly alarm request. The data analysis equipment sends an abnormal alarm request to the abnormal alarm module aiming at the abnormal data if one or more items in the acquired first operation data and second operation data are analyzed to be inconsistent with a preset numerical value range, so that the abnormal alarm module responds to the abnormal alarm request and alarms aiming at the abnormal data. For example, if the data analysis device analyzes that the temperature value is greater than a preset temperature value range for the obtained temperature value in the high-voltage distribution device, the data analysis device sends an abnormality alarm request to the abnormality alarm module for the temperature value, so that the abnormality alarm module responds to the abnormality alarm request and alarms for the temperature value in the high-voltage distribution device.

In this embodiment, the abnormality alarm module may receive an abnormality alarm request sent by the upper computer when the analyzed operating state of the second switch in the first operating data does not correspond to the on or off state of the production equipment in the second operating data, and may perform an abnormality alarm in response to the abnormality alarm request. Therefore, the accuracy of low-voltage power distribution can be improved through comprehensive analysis of the first operation data and the second operation data, and the reliability of a low-voltage power distribution system is improved.

As shown in fig. 2, the shop production module also includes a fire fighting module 23. The upper computer 31 is connected with the fire fighting module 23 through optical fibers (the connection relationship is not shown in fig. 2). Wherein, the fire fighting module 23 can include a fire fighting monitoring device 231 and a fire fighting device 232, and the fire fighting monitoring device 231 and the fire fighting device 232 are respectively connected with the upper computer 31 through optical fibers.

In this embodiment, the abnormal signal that fire control monitoring devices monitored can pass through optical fiber transmission to the host computer, and the host computer confirms corresponding fire-fighting equipment according to the abnormal signal that receives to send control signal to corresponding fire-fighting equipment through optic fibre, so that fire-fighting equipment responds to control signal and opens, has improved production facility's security.

As shown in fig. 2, the integrated management platform includes an uninterruptible power supply unit 34. The uninterruptible power supply device 34 is connected to the utility power supply 40, and is respectively connected to the first data processing device 10, the second data processing device 21, the upper computer 31, the lower computer (i.e., the data analysis device 30), the data acquisition device 32, the first monitoring device 14, the second monitoring device 22, the abnormality alarm module 33, and the fire monitoring device 231.

In this embodiment, through the uninterrupted power source device for first data processing device, second data processing device, host computer, lower computer, data acquisition equipment, first monitoring device, second monitoring device, unusual alarm module and fire control monitoring devices carry out uninterrupted power supply, can realize the real-time analysis and the control to low-voltage distribution system, avoided being difficult to the condition of discovering equipment trouble or potential safety hazard under the circumstances that the commercial power has a power failure, improved low-voltage distribution system's security.

The working principle of the low-voltage distribution system based on the oil sludge treatment station shown in fig. 2 is explained in detail as follows:

first, the first data processing device 10 in the low-voltage power distribution module can acquire first operation data in the high-voltage power distribution device 11 and the low-voltage power distribution device 12, and transmit the first operation data to the data analysis device 30 in the integrated management platform through an optical fiber. The second data processing device 21 in the workshop production module can acquire the second operation data of the production equipment 20 and transmit the second operation data to the data analysis equipment 30 in the integrated management platform through the optical fiber.

Secondly, each data analysis device 30 in the integrated management platform responds to the instruction issued by the upper computer 31 respectively, performs archive analysis on the first operation data and the second operation data, and sends the instruction issued by the upper computer 31 to the first data processing device 10 and the second data processing device 21, so that the first data processing device 10 and the second data processing device 21 execute corresponding control operation based on the received instruction respectively.

Then, the data obtaining device 32 in the integrated management platform can receive the monitoring data in the first monitoring device 14 in the low-voltage power distribution module and the second monitoring device 22 in the workshop production module based on a wireless transmission or wired transmission mode, and communicate with the upper computer through RS485, so that the monitoring data obtained from the first monitoring device 14 and the second monitoring device 22 is sent to the upper computer 31, and the upper computer 31 comprehensively analyzes the monitoring data, the first operating data of the low-voltage power distribution module and the second operating data of the workshop production module, which are obtained through the data analysis device 30.

Furthermore, the anomaly alarm module 33 in the integrated management platform can receive an anomaly alarm request sent by each data analysis device 30 when the data is analyzed to be anomalous, and can respond to the anomaly alarm request to perform anomaly alarm, and can receive an anomaly alarm request sent by the upper computer 31 when the working state of the second switch in the first operation data and the on or off state of the production device 20 in the second operation data are analyzed to be not corresponding, and can respond to the anomaly alarm request to perform anomaly alarm.

Furthermore, abnormal signals monitored by the fire monitoring device 231 in the fire module 23 in the workshop production module can be transmitted to the upper computer 31 through optical fibers, the upper computer 31 determines the corresponding fire fighting equipment 232 according to the received abnormal signals, and sends control signals to the corresponding fire fighting equipment 232 through the optical fibers, so that the fire fighting equipment 232 is started in response to the control signals.

Moreover, the uninterruptible power supply device 34 in the integrated management platform can supply power to the first data processing device, the second data processing device, the upper computer, the lower computer, the data acquisition equipment, the first monitoring device, the second monitoring device, the abnormity alarm module and the fire monitoring device uninterruptedly.

In the low voltage distribution system based on sludge treatment station that this application embodiment provided, because low voltage distribution module includes interconnect's first data processing apparatus, high voltage distribution device and low voltage distribution device, be connected with the transformer between high voltage distribution device and the low voltage distribution device, workshop production module includes interconnect's production facility and second data processing apparatus, the integrated management platform includes two at least data analysis equipment, each data analysis equipment is connected with first data processing apparatus and second data processing apparatus respectively. Therefore, the low-voltage power distribution system can achieve the effect of analyzing the data of production equipment, a high-voltage power distribution device and a low-voltage power distribution device in the comprehensive management platform, so that the purpose of controlling the power supply condition between the low-voltage power distribution module and the workshop production module through the comprehensive management platform is achieved, the effect of intelligently conducting low-voltage power distribution on the oil sludge treatment station is achieved, and the power utilization safety of the oil sludge treatment station is improved.

In summary, particular embodiments of the present subject matter have been described. Other embodiments are within the scope of the following claims. In some cases, the actions recited in the claims can be performed in a different order and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing may be advantageous.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. A low-voltage power distribution system based on an oil sludge treatment station is characterized by comprising a low-voltage power distribution module, a comprehensive management platform and a workshop production module which are connected with each other; wherein the content of the first and second substances,

the low-voltage power distribution module comprises a first data processing device, a high-voltage power distribution device and a low-voltage power distribution device which are connected with each other; a transformer is connected between the high-voltage distribution device and the low-voltage distribution device;

the workshop production module comprises production equipment and a second data processing device which are connected with each other;

the integrated management platform comprises at least two data analysis devices, and each data analysis device is connected with the first data processing device and the second data processing device respectively.

2. The system of claim 1, wherein the data analysis device is a lower computer; the comprehensive management platform further comprises an upper computer connected with the lower computer.

3. The system of claim 1, wherein the high voltage power distribution device includes a first switch and a first circuit breaker therein; the low-voltage distribution device comprises a second switch and a second circuit breaker; the first switch, the first circuit breaker, the second switch and the second circuit breaker are respectively connected with the first data processing device.

4. The system of claim 2, wherein the integrated management platform further comprises an uninterruptible power supply device; the uninterrupted power supply device is connected with a mains supply and respectively supplies power to the first data processing device, the second data processing device, the upper computer and the lower computer.

5. The system of claim 4, wherein the integrated management platform further comprises a data acquisition device; the low-voltage power distribution module further comprises a first monitoring device; the workshop production module also comprises a second monitoring device;

the data acquisition equipment is respectively connected with the first monitoring device, the second monitoring device and the upper computer.

6. The system of claim 5, wherein the uninterruptible power supply device is respectively electrically connected to the data acquisition equipment, the first monitoring device, and the second monitoring device.

7. The system of claim 4, wherein the shop production module further comprises a fire fighting module; the upper computer is connected with the fire-fighting module through optical fibers.

8. The system of claim 5, wherein the integrated management platform further comprises an exception alert module; the abnormality alarm module is respectively connected with the upper computer and the at least two data analysis devices; and the uninterrupted power supply device supplies power and is connected to the abnormity alarm module.

9. The system of claim 1, wherein the first data processing device and/or the second data processing device is a distributed input/output cabinet.

10. The system of claim 5, wherein the second monitoring device is an explosion-proof camera.

Images