CN110908453A - Warning type server case for vehicle-mounted water quality monitoring - Google Patents

Abstract

A warning server case for vehicle-mounted water quality monitoring comprises a case body and a cover plate; the upper wall of the box body is provided with an exhaust groove which is communicated with the hollow interior of the box body and is used as an exhaust passage; the cover plate is arranged on the upper wall of the box body and forms a certain spacing space with the upper wall; the cover plate covers the exhaust groove entirely within the range of the upper wall. A temperature relay is arranged in the box body, the temperature relay is provided with a normally open contact, and the normally open contact is connected between the buzzer and a power supply of the buzzer in series; the buzzer is arranged on the outer wall of the box body. The upper wall of box sets up the hydrops mouth to exhaust duct collapse in the periphery of exhaust duct, and the liquid in the hydrops mouth is close the limit wall separation on one side of exhaust duct in the hydrops mouth by the hydrops mouth, has one section to be the flowing back groove with outside intercommunication in the limit wall on one side that the hydrops mouth is farther apart from the exhaust duct, this flowing back groove and a drain pipe intercommunication. The server case effectively avoids the defect of poor liquid blocking effect in the prior art.

Description

Warning type server case for vehicle-mounted water quality monitoring

Technical Field

The invention relates to the technical field of vehicle-mounted water quality monitoring, in particular to a warning server case for vehicle-mounted water quality monitoring.

Background

Environmental emergency monitoring refers to monitoring of pollutant types, quantities, concentrations, pollution ranges, ecological damage degrees, ranges and the like under environmental emergency conditions after an emergency environmental event occurs. The method aims to discover and find out the types, the amounts, the concentrations and the pollution range of pollutants after an emergent environmental event and master the ecological damage range and the ecological damage degree after the emergent environmental event. The environmental emergency monitoring includes monitoring of events such as major pollution accident, sudden pollution accident, natural disaster causing major influence on the environment, and the like, and monitoring of measures required to be taken when abnormal conditions are found in the processes of environmental quality monitoring and pollution source monitoring, and the like, and can be divided into fixed-point monitoring and dynamic monitoring, and the dynamic monitoring generally adopts a vehicle-mounted monitoring system. The traditional environment emergency monitoring system has the following technical problems: monitoring instruments and equipment of a traditional environment emergency monitoring system are not completely equipped, for example, some monitoring equipment are only equipped with gas pollution, and emergency monitoring of water body pollution cannot be realized, so that monitoring strength is insufficient, a monitoring result cannot reflect an actual situation, and emergency decision of related departments is seriously influenced; the traditional environment emergency monitoring system lacks organic systematic integration in the aspects of continuous real-time data acquisition, instant transmission, space analysis based on data results and emergency decision, so that the emergency monitoring front-end equipment and the environment emergency decision support system lack close organic association, and the system efficiency is limited to be exerted.

Thus, warning vehicle-mounted water quality monitoring equipment with the application number of 201320247745.9, the application date of 2013.05.09 and the patent name of vehicle-mounted environment emergency monitoring system appears.

The vehicle-mounted environment emergency monitoring system comprises a gas monitoring device 1, a water quality monitoring device 2, a radiation monitoring device 3, a gas phase monitoring device 4, a GPS locator 5, a video monitoring device 6, a data acquisition and processing device 7, a monitoring computer 8 arranged in an emergency monitoring center, a disaster prevention and reduction department database server 9 and aerial monitoring equipment as shown in figures 1-2.

The gas monitoring device 1, the water quality monitoring device 2, the radiation monitoring device 3, the gas phase monitoring device 4, the GPS locator 5 and the video monitoring device 6 are in data connection with the data acquisition and processing device 7 and the monitoring computer 8 of the emergency monitoring center through a wireless communication module 10; the data acquisition and processing device 7 is also in data connection with the monitoring computer 8 platform through a wireless communication module 10, and the monitoring computer 8 is in data connection with the disaster prevention and reduction department database server 9 through a wired local area network.

The water quality monitoring device 2 comprises one or more of a water quality analyzer comprising a Chemical Oxygen Demand (COD) analyzer, a biological oxidation oxygen demand analyzer, a total organic carbon analyzer, a total oxygen demand analyzer, an ammonia nitrogen analyzer, a total phosphorus analyzer, a metal ion analyzer, a pH value analyzer, a turbidity analyzer and a suspended matter analyzer.

The radiation monitoring device 3 comprises one or more of a gamma radiation automatic monitoring GP-110 detector, an ADM606 measuring instrument, a BrLa portable gamma spectrometer and a dose rate meter.

The gas phase monitoring device 4 comprises one or more of a temperature sensor, a humidity sensor and a pressure sensor;

the video monitoring device 6 comprises one or more of a camera, a daylight type color camera, a low-light level black and white camera and an infrared thermal camera.

The aerial monitoring equipment comprises an unmanned helicopter, the unmanned helicopter is provided with a gas rapid analyzer 21, a meteorological parameter detector 22, a video acquisition device 23, a GPS clock control module 24 and a PLC (programmable logic controller) 25, the output end of the GPS clock control module 24 is connected with the input end of the PLC 25, the PLC control output end is connected with the control ends of the gas rapid analyzer 21, the meteorological parameter detector 22 and the video acquisition device 23, and the gas rapid analyzer 21, the meteorological parameter detector 22 and the video acquisition device 23 are in data connection with the data acquisition processing device 7 and the monitoring computer 8 of the emergency monitoring center through a wireless communication module 10.

The meteorological parameter detector 22 includes one or more of a temperature sensor, a humidity sensor, and a pressure sensor.

The gas monitoring device 1 comprises a sampling probe 11, a filter 12, an air inlet pump 13, a sensor array 14, a signal preprocessing singlechip 15 and a central processing unit 16, wherein the sampling probe 11, the filter 12 and the air inlet pump 13 are sequentially connected, and the sensor array 14 detects gas collected by the sampling probe 11, filtered by the filter 12 and sent by the air inlet pump 13; the output end of the sensor array 14 is connected with the input end of the signal preprocessing single chip microcomputer 15, the output end of the signal preprocessing single chip microcomputer 15 is connected with the input end of the central processing unit 16, and the central processing unit 16 is connected with the wireless communication module 10 in a bidirectional mode.

The sensor array 14 includes a plurality of sensors capable of detecting one or more harmful gases of CO, H2S, SO2, NO2, NO, CI2, HCN, HN3, PH3, CIO2, HCI, VOC.

The monitoring instrument and the equipment of the environment emergency monitoring system are complete, the system is provided with a gas monitoring device, a water quality monitoring device, a radiation monitoring device, a gas phase monitoring device, a GPS (global positioning system) positioning instrument and a video monitoring device, and can effectively monitor polluted gas, polluted water and radiation, so that the emergency environment monitoring basic data is more perfect, the monitoring result is closer to the actual situation, and perfect reference data is provided for the emergency decision of relevant departments.

The environment emergency monitoring system also adopts aerial monitoring equipment and a GPS clock control module, collects aerial monitoring data of the emergency environment based on a GPS reference clock, adopts a wireless communication module to transmit data through a wireless network, and carries out organic systematic integration on continuous real-time acquisition and real-time transmission of the data, and space analysis and emergency decision based on data results, so that the emergency monitoring front-end equipment and the environment emergency decision support system are closely and organically associated, and the performance of the system efficiency is ensured.

In order to avoid damage caused by external impact, the database server is placed in a hollow server case, the server case needs to have a good liquid blocking effect, liquid flow caused by condition change in a room where the server case is located due to various accidents can be prevented from permeating into the server case, and liquid leakage of a liquid pipeline laid on a ceiling in the room onto the server case can be prevented, however, the existing case structure can only avoid external impact on the database server, and the liquid blocking effect is poor. In addition, the temperature in the server chassis generally needs to be kept in a range below 45 ℃ to enable the database server to work normally, but currently, no temperature prompting device is used for warning whether the temperature of the server chassis exceeds the temperature for enabling the database server to work normally.

Disclosure of Invention

In order to solve the problems, the invention provides a liquid-blocking agent which can effectively avoid the defect of poor liquid-blocking effect in the prior art.

In order to overcome the defects in the prior art, the invention provides a warning vehicle-mounted water quality monitoring device and a solution of the warning vehicle-mounted water quality monitoring method, which specifically comprise the following steps:

a warning vehicle-mounted server chassis for water quality monitoring comprises a box body and a cover plate, and is characterized in that an exhaust groove which is communicated with the hollow interior of the box body and is used as an exhaust passage is formed in the upper wall of the box body;

the cover plate is arranged on the upper wall of the box body and forms a certain spacing space with the upper wall; the cover plate covers the whole exhaust groove in the covering range of the upper wall;

the box body is internally provided with a temperature relay, the temperature relay is provided with a normally open contact, and the normally open contact is connected between the buzzer and a power supply of the buzzer in series;

the buzzer is arranged on the outer wall of the box body;

the upper wall of box sets up the hydrops mouth to the exhaust duct collapse in the periphery of exhaust duct, liquid in the hydrops mouth is close the limit wall separation on one side of exhaust duct in the hydrops mouth by the hydrops mouth, it is the flowing back groove with outside intercommunication to have one section in the limit wall on one side that the hydrops mouth is farther apart from the exhaust duct, this hydrops mouth and a drain pipe intercommunication.

The invention has the beneficial effects that:

1. the cover plate B is arranged on the upper wall of the box body A and forms a certain spacing space with the upper wall; the cover plate B covers the whole exhaust groove A1 in the covering range of the upper wall; therefore, the cover plate B can block the liquid flow dropping from top to bottom, and the liquid flow can not drop into the case 1, thereby forming a primary liquid blocking structure.

2. The upper wall of the box body A is provided with a liquid accumulation port A2, and a boundary wall is arranged between the liquid accumulation port A2 and an exhaust groove A1 serving as an exhaust passage to block, so that liquid in the liquid accumulation port A2 is prevented from seeping into the exhaust passage. In addition, a section of the side wall of the liquid accumulation port A2 is provided with a columnar liquid discharge groove AB3 communicated with the outside, so that the liquid in the liquid accumulation port A2 can be discharged efficiently through the columnar liquid discharge groove AB; the liquid trap A2 constitutes a further liquid blocking structure, and when the liquid drops to the upper wall of the cabinet over the cover plate B, the liquid drops into the liquid trap A2 and is discharged.

Drawings

Fig. 1 is a schematic structural diagram of a vehicle-mounted environment emergency monitoring system in the prior art.

Fig. 2 is a schematic structural view of the gas monitoring device of fig. 1.

Fig. 3 is a three-dimensional schematic diagram of a server chassis of the present invention.

Fig. 4 is a schematic structural view of the cover plate of the present invention.

Fig. 5 is a structural view of the upper wall of the server casing of the present invention.

Fig. 6 is a connection diagram of the temperature relay of the present invention.

Detailed Description

The invention will be further described with reference to the following figures and examples.

As shown in fig. 1 to 6, the warning vehicle-mounted water quality monitoring device includes a gas monitoring device 1, a water quality monitoring device 2, a radiation monitoring device 3, a gas phase monitoring device 4, a GPS locator 5, a video monitoring device 6, a data acquisition and processing device 7, a monitoring computer 8 arranged in an emergency monitoring center, a database server 9 of a disaster prevention and reduction department, and an aerial monitoring device;

the gas monitoring device 1, the water quality monitoring device 2, the radiation monitoring device 3, the gas phase monitoring device 4, the GPS locator 5 and the video monitoring device 6 are in data connection with the data acquisition and processing device 7 and the monitoring computer 8 of the emergency monitoring center through the wireless communication module 10; the data acquisition processing device 7 is also in data connection with a monitoring computer 8 platform through a wireless communication module 10, and the monitoring computer 8 is in data connection with a disaster prevention and reduction department database server 9 through a wired local area network;

the water quality monitoring device 2 comprises one or more of a water quality analyzer including a Chemical Oxygen Demand (COD) analyzer, a biological oxidation oxygen demand analyzer, a total organic carbon analyzer, a total oxygen demand analyzer, an ammonia nitrogen analyzer, a total phosphorus analyzer, a metal ion analyzer, a pH value analyzer, a turbidity analyzer and a suspended matter analyzer.

The radiation monitoring device 3 comprises one or more of a gamma radiation auto-monitoring GP-110 detector, an ADM606 measuring instrument, a BrLa portable gamma spectrometer and a dose rate meter.

The gas phase monitoring device 4 comprises one or more of a temperature sensor, a humidity sensor and a pressure sensor;

the video monitoring device 6 includes one or more of a camera, a daylight-type color camera, a low-light black-and-white camera, and an infrared thermography camera.

Aerial monitoring facilities includes unmanned vehicles, unmanned vehicles is unmanned helicopter, unmanned helicopter is last to be provided with gaseous rapid analysis appearance 21, meteorological parameter detector 22, video acquisition device 23, GPS clock control module 24 and PLC controller 25, GPS clock control module 24's output and PLC controller 25 input are connected, PLC control output and gaseous rapid analysis appearance 21, meteorological parameter detector 22, video acquisition device 23 control end is connected, gaseous rapid analysis appearance 21, meteorological parameter detector 22, video acquisition device 23 all carries out data connection through wireless communication module 10 and data acquisition processing apparatus 7, emergency monitoring center's supervisory control computer 8.

The meteorological parameter detector 22 includes one or more of a temperature sensor, a humidity sensor, and a pressure sensor.

The gas monitoring device 1 comprises a sampling probe 11, a filter 12, an air inlet pump 13, a sensor array 14, a signal preprocessing singlechip 15 and a central processing unit 16, wherein the sampling probe 11, the filter 12 and the air inlet pump 13 are sequentially connected, and the sensor array 14 detects gas collected by the sampling probe 11, filtered by the filter 12 and sent by the air inlet pump 13; the output end of the sensor array 14 is connected with the input end of the signal preprocessing single chip microcomputer 15, the output end of the signal preprocessing single chip microcomputer 15 is connected with the input end of the central processing unit 16, and the central processing unit 16 is connected with the wireless communication module 10 in a bidirectional mode.

The sensor array 14 includes a plurality of sensors capable of detecting one or more harmful gases of CO, H2S, SO2, NO2, NO, CI2, HCN, HN3, PH3, CIO2, HCI, VOC.

The monitoring instrument and the equipment of the environment emergency monitoring system are complete, the system is provided with a gas monitoring device, a water quality monitoring device, a radiation monitoring device, a gas phase monitoring device, a GPS (global positioning system) positioning instrument and a video monitoring device, and can effectively monitor polluted gas, polluted water and radiation, so that the emergency environment monitoring basic data is more perfect, the monitoring result is closer to the actual situation, and perfect reference data is provided for the emergency decision of relevant departments.

The environment emergency monitoring system also adopts aerial monitoring equipment and a GPS clock control module, collects aerial monitoring data of the emergency environment based on a GPS reference clock, adopts a wireless communication module to transmit data through a wireless network, and carries out organic systematic integration on continuous real-time acquisition and real-time transmission of the data, and space analysis and emergency decision based on data results, so that the emergency monitoring front-end equipment and the environment emergency decision support system are closely and organically associated, and the performance of the system efficiency is ensured.

The database server is placed in a hollow server case, and the server case comprises a case body A and a cover plate B; the upper wall of the box body A is provided with a columnar exhaust groove A1 which is communicated with the hollow interior of the box body A and is used as an exhaust passage;

the cover plate B is arranged on the upper wall of the box body A and forms a certain spacing space with the upper wall; the cover plate B covers the exhaust groove A1 in the whole range covered by the upper wall; therefore, the cover plate B can block the liquid flow dropping from top to bottom, and the liquid flow can not drop into the case 1, thereby forming a primary liquid blocking structure.

The upper wall of the box body A is provided with a liquid accumulation port A2 sunk towards the exhaust groove A1 at the periphery of the exhaust groove A1, and liquid in the liquid accumulation port A2 is blocked in the liquid accumulation port A2 by a side wall AB1 at one side of the liquid accumulation port A2 close to the exhaust groove A1;

a temperature relay is arranged in the box body A, the temperature relay is provided with a normally open contact, and the normally open contact is connected between the buzzer and a power supply of the buzzer in series;

the buzzer is arranged on the outer wall of the box body A.

A column-shaped liquid discharge groove AB3 communicated with the outside is arranged in the side wall AB2 of the liquid accumulation port A2 at the side farther from the air discharge groove A1. The upper wall of the box body A is provided with a liquid accumulation port A2, and a boundary wall is arranged between the liquid accumulation port A2 and an exhaust groove A1 serving as an exhaust passage to block, so that liquid in the liquid accumulation port A2 is prevented from seeping into the exhaust passage. In addition, a section of the side wall of the liquid accumulation port A2 is provided with a columnar liquid discharge groove AB3 communicated with the outside, so that the liquid in the liquid accumulation port A2 can be discharged efficiently through the columnar liquid discharge groove AB; the liquid trap A2 constitutes a further liquid blocking structure, and when the liquid drops to the upper wall of the cabinet over the cover plate B, the liquid drops into the liquid trap A2 and is discharged.

The box body A is hinged with a plate-shaped cover plate on one side wall, the plate-shaped cover plate is used for respectively communicating and isolating the inside and the outside of the box body A through opening and closing, and therefore the cover plate needs to be opened from time to maintain the inside of the box body A, so that liquid drops and particulate impurities need to be prevented from being accumulated on the top of the cover plate of the box body A, and the liquid drops and the particulate impurities are prevented from seeping into the box body A when the cover plate is opened. To achieve this effect, one edge of the upper wall of the box body a protrudes outward beyond the coverage of the cover plate B, and a portion of the upper wall of the box body a protruding outward beyond the coverage of the cover plate B is provided with a first flap a3 in a downwardly inclined sheet shape.

To achieve the assembly of the cover plate B and the box body A, a columnar positioning opening A5 for assembling a strip-shaped supporting rod A4 is arranged in the liquid accumulation opening A2, one end of the supporting rod A4 is embedded with the positioning opening A5, and the other end of the supporting rod A4 is connected with the bottom wall of the cover plate B.

When the liquid flow is not enough, the upper wall of the cover plate B has accumulated liquid flow, and in order to discharge the liquid flow in real time, the periphery of the upper wall of the cover plate B is provided with various downwards inclined drainage walls B1. The liquid flow can be efficiently discharged through the inclined drainage wall B1.

The coverage of the drainage wall B1 is outside the upper wall of the box body A. The liquid stream dripping directly on the cover plate B cannot drip into the box a. In addition, the covering area of the drainage wall B1 can be within the range of the upper wall of the box body A, so that the liquid can drip into the liquid collecting port A2 through the drainage wall.

The upper limit temperature of the temperature relay is set to 45 degrees.

Therefore, the upper temperature limit value of the temperature relay is set to be 45 degrees, the temperature in the box body of the server case exceeds 45 degrees, the normally open contact of the temperature relay is closed, the power supply of the buzzer and the buzzer is switched on, and the buzzer sends out buzzing, so that the temperature of the server case is warned to exceed the temperature for enabling the database server to normally work.

The present invention has been described in an illustrative manner by the embodiments, and it should be understood by those skilled in the art that the present disclosure is not limited to the embodiments described above, but is capable of various changes, modifications and substitutions without departing from the scope of the present invention.

Claims (3)

1. A warning vehicle-mounted server chassis for water quality monitoring comprises a box body and a cover plate, and is characterized in that an exhaust groove which is communicated with the hollow interior of the box body and is used as an exhaust passage is formed in the upper wall of the box body;

the cover plate is arranged on the upper wall of the box body and forms a certain spacing space with the upper wall; the cover plate covers the whole exhaust groove in the covering range of the upper wall;

the box body is internally provided with a temperature relay, the temperature relay is provided with a normally open contact, and the normally open contact is connected between the buzzer and a power supply of the buzzer in series;

the buzzer is arranged on the outer wall of the box body;

the upper wall of box sets up the hydrops mouth to the exhaust duct collapse in the periphery of exhaust duct, liquid in the hydrops mouth is close the limit wall separation on one side of exhaust duct in the hydrops mouth by the hydrops mouth, there is one section to be the flowing back groove with outside intercommunication in the limit wall on one side that the hydrops mouth is farther apart from the exhaust duct, this flowing back groove and a drain pipe intercommunication.

2. A warning vehicle-mounted water quality monitoring server case according to claim 1, wherein a plate-shaped cover plate is hinged to one side wall of the case, one side of the upper wall of the case protrudes outwards beyond the coverage of the cover plate, and a first downward-inclined plate-shaped baffle is arranged at a part of the upper wall of the case, which protrudes outwards beyond the coverage of the cover plate.

3. The server case for warning vehicle-mounted water quality monitoring according to claim 2, wherein a positioning hole for assembling a supporting rod is formed in the liquid accumulating hole, one end of the supporting rod is embedded with the positioning hole, and the other end of the supporting rod is connected with the bottom wall of the cover plate.

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