CN115178305A

CN115178305A - Monitoring cloud platform

Info

Publication number: CN115178305A
Application number: CN202210868745.4A
Authority: CN
Inventors: 孙世国; 徐全铭; 王家慧; 张航
Original assignee: Jiangsu Gude Operation And Maintenance Information Technology Co ltd
Current assignee: Jiangsu Gude Operation And Maintenance Information Technology Co ltd
Priority date: 2022-07-22
Filing date: 2022-07-22
Publication date: 2022-10-14

Abstract

The invention provides a monitoring cloud platform, which relates to the technical field of cloud platforms and comprises an explosion-proof experiment cabinet, wherein a first reaction device and a second reaction device are arranged in the explosion-proof experiment cabinet, the first reaction device is arranged at the front end of the second reaction device, the first reaction device comprises a reaction container and a gas collection device, and the top of the reaction container is movably connected with the bottom of the gas collection device. According to the invention, the smell generated by the reaction, the leakage and the pressure can be transmitted to the remote monitoring platform through the gas sensor, the touch sensor and the differential pressure sensor, the camera device transmits a real-time picture to the remote monitoring platform, so that an experimenter can know the reaction condition of a chemical experiment in real time and perform corresponding operation, the automatic quantitative and accurate chemical liquid transfer is realized through the transfer device, the monitoring cloud platform automatically transmits the reaction information to the remote monitoring platform, and meanwhile, the experimenter is prevented from being injured due to dangerous experiments.

Description

Monitoring cloud platform

Technical Field

The invention relates to the technical field of cloud platforms, in particular to a monitoring cloud platform.

Background

The cloud computing platform is also called a cloud platform, and is a service based on hardware resources and software resources, and provides computing, network and storage capabilities, and can be divided into 3 types: in a chemical laboratory, such as the configuration of chemical reagents and the like, the storage cloud platform mainly based on data storage, the computing cloud platform mainly based on data processing and the comprehensive cloud computing platform considering both computing and data storage processing are basic operations which are necessarily contacted by all subjects related to the chemical field, and various physical or chemical reactions often occur in the chemical experimental process to generate various reaction phenomena.

However, in the prior art, some dangerous property changes, such as irritation, corrosivity, toxicity, flammability, explosiveness, carcinogenicity, etc., are unavoidable in the chemical experiment process, at present, an experimenter basically performs direct operation during chemical experiments, and is completely exposed to various chemical reagents or various reactions, even performs dangerous chemical operation or reactions which are very dangerous or unknown, the experimenter often only can stand in front of dangerous hidden dangers with hands with increased vigilance, so that accidents which are harmful to the health of the experimenter or even endanger the life often occur, and the observation time of some chemical experiments is too long, the experimenter needs to stay in a laboratory all the time, a monitoring cloud platform which can transmit data to a remote monitoring platform through a sensor is urgently needed, and meanwhile, a real-time picture is transmitted to the remote monitoring platform through monitoring camera shooting, so that the experimenter can know the reaction condition of the chemical experiment in real time through the remote monitoring platform and perform corresponding operations.

Disclosure of Invention

The invention aims to solve the defects in the prior art, by adopting an explosion-proof experiment cabinet capable of realizing the function of monitoring a cloud platform, when a reaction bottle or a reaction container in the explosion-proof experiment cabinet and a user perform experiments, an experimenter can put reactants into the reaction container and well adjust various reaction parameters, a gas sensor, a touch sensor and a differential pressure sensor can transmit information such as smell, leakage, pressure and the like generated by the reaction to a remote monitoring platform, a real-time picture is transmitted to the remote monitoring platform through a camera device, the experimenter can know the reaction condition of the chemical experiment in real time through the remote monitoring platform and perform corresponding operation, and can automatically and orderly quantitatively and accurately transfer chemical liquid when chemical solution is prepared through the chemical reaction, so that chemical reagents are mixed, meanwhile, a magnetic stirrer performs corresponding operation on the reaction bottle needing to be heated or stirred, the reaction can be promoted, the purpose that the experimenter stays beside the reaction container to observe at any time is achieved, and the monitoring cloud platform automatically transmits the reaction information to the remote monitoring platform, and simultaneously, the experimenter is prevented from being damaged by danger.

In order to achieve the purpose, the invention adopts the following technical scheme: the utility model provides a control cloud platform, includes explosion-proof experiment cabinet, the inside of explosion-proof experiment cabinet is provided with first reaction unit and second reaction unit, first reaction unit sets up the front end at second reaction unit, first reaction unit includes reaction vessel and gas collection device, reaction vessel's top and gas collection device's bottom swing joint, gas collection device includes apron, touch-control sensor and gas collecting bottle, the bottom of apron and reaction vessel's top fixed connection, the top fixedly connected with reaction cover of apron, the gaseous defeated pipe of top fixedly connected with of apron, the top fixedly connected with air exhaust component of gaseous defeated pipe, air exhaust component's top and gas collecting bottle's bottom swing joint, gas collecting bottle sets up the bottom at the reaction cover, gas collecting bottle's bottom is provided with the gas sensor, the annular has been seted up at the top of apron, one side fixedly connected with touch-control sensor of annular.

As a preferred embodiment, the explosion-proof experimental cabinet comprises a cabinet body and a supporting experiment table, wherein the bottom of the inner side of the cabinet body is fixedly connected with the bottom of the supporting experiment table, and the top of the supporting experiment table is fixedly connected with an experiment board.

As a preferable embodiment, the top front end of the experiment board is provided with a pressure plate, the reaction vessel is arranged on the top of the pressure plate, the bottom of the pressure plate is provided with a differential pressure sensor, and the bottom of the cabinet body is uniformly provided with a plurality of bottom posts.

As a preferred embodiment, a pressure plate is arranged at the front end of the top of the experiment board, a differential pressure sensor is arranged at the bottom of the pressure plate, and a plurality of bottom posts are uniformly arranged at the bottom of the cabinet body.

As a preferred embodiment, a front end door is arranged at the front end of the cabinet body, and a rear end door is arranged at the rear end of the cabinet body.

As a preferred embodiment, the top of the cabinet body is fixedly connected with an alarm device, and the inner side of the top of the cabinet body is provided with a camera device.

As a preferred embodiment, the second reaction device comprises a transfer device, reaction bottles and three magnetic stirrers, the magnetic stirrers are uniformly arranged on the top of the experimental plate, and the bottoms of the reaction bottles are movably connected with the tops of the magnetic stirrers.

As a preferred embodiment, the transfer device comprises a support frame and a shell plate, wherein the bottom of the support frame is fixedly connected with the top of the experiment plate, and the top of the support frame is movably connected with two ends of the shell plate.

As a preferred embodiment, a plurality of peristaltic pumps are arranged inside the outer shell plate, the number of the peristaltic pumps is two, a liquid pumping pipe is fixedly connected to the bottom of each peristaltic pump, and a liquid outlet pipe is fixedly connected to one side of each peristaltic pump.

As a preferred embodiment, the bottom of the liquid pumping pipe is movably connected with the top of the reaction bottle, and the bottom of the liquid outlet pipe is movably connected with the top of the reaction bottle.

Compared with the prior art, the invention has the advantages and positive effects that,

1. according to the explosion-proof experiment cabinet, the alarm device and the camera device are combined, the cabinet body is made of stainless steel plate materials for pressure-bearing equipment, the inner wall of the cabinet body is a solid physicochemical plate with corrosion resistance, antibiosis, ultraviolet resistance and the like, the explosion-proof and durable effects are achieved, the alarm device automatically gives out alarm sound when a bad condition occurs in the experiment to remind other experimenters, the camera device transmits all-dimensional pictures in the reaction container of the cabinet body to the remote monitoring platform in real time in the experiment process, and the experimenters can conveniently observe and operate.

2. According to the invention, through the arrangement of the differential pressure sensor, the gas sensor and the air exhaust assembly of the first reaction device, when a chemical experiment reaction is carried out in the reaction vessel, the differential pressure sensor transmits the pressure in the reaction vessel to the remote monitoring platform in real time, an experimenter can automatically obtain reaction data according to the pressure difference between the beginning and the end, the gas sensor carries out smell detection on the gas generated by the reaction and transmits the smell detection to the remote monitoring platform, the air exhaust assembly automatically exhausts the gas in the reaction vessel into the gas collecting bottle in the reaction process, and the smell of the gas generated by the chemical reaction and the reaction amount are automatically transmitted to the experimenter, so that the operation is convenient and safe.

3. According to the invention, the annular groove and the touch sensor are arranged on the cover plate at the top of the reaction container, when a small amount of chemical reagent in the reaction container overflows, the annular groove touches the touch sensor, the touch sensor transmits information to the remote monitoring platform in time, and an experimenter can remotely operate the alarm device to sound to remind the experimenter to process, so that the reagent leakage is avoided.

4. According to the invention, by additionally arranging the transfer device, reagents are placed into corresponding reaction bottles according to the requirements of chemical experiments, all the reaction bottles are placed on the magnetic stirrer, the liquid pumping pipe and the liquid outlet pipe are connected, the experimenter sets reaction parameters through the remote monitoring platform, the transfer device sequentially carries out quantitative accurate liquid pumping to mix the chemical reagents, and the magnetic stirrer carries out corresponding operation on a reaction container needing to be heated or stirred, so that the reaction is promoted.

Drawings

FIG. 1 is a front perspective view of a surveillance cloud platform according to the present invention;

FIG. 2 is a rear perspective view of a monitoring cloud platform according to the present invention;

fig. 3 is a bottom perspective view of a monitoring cloud platform according to the present invention;

FIG. 4 is a schematic structural diagram of a first reaction apparatus for monitoring a cloud platform according to the present invention;

FIG. 5 is a schematic structural diagram of a second reaction device of a monitoring cloud platform according to the present invention;

FIG. 6 is a bottom perspective view of a first reactor of a monitoring cloud platform according to the present invention;

fig. 7 is a sectional view of a transfer device of a monitoring cloud platform according to the present invention;

FIG. 8 is a cross-sectional view of a gas collection apparatus for monitoring a cloud platform in accordance with the present invention;

fig. 9 is a bottom perspective view of a gas collection device of a surveillance cloud platform according to the present invention.

Illustration of the drawings:

1. an explosion-proof experimental cabinet; 2. a first reaction device; 3. a second reaction device; 10. a camera device; 11. a cabinet body; 12. a front end door; 13. a rear end door; 14. supporting the experiment table; 15. an experimental plate; 16. a bottom pillar; 17. A pressure plate; 18. a differential pressure sensor; 19. an alarm device; 21. a reaction vessel; 22. a gas collection device; 31. a transfer device; 32. a reaction bottle; 33. a magnetic stirrer; 221. a cover plate; 222. a reaction hood; 223. a ring groove; 224. a gas delivery pipe; 225. a touch sensor; 226. a gas collection bottle; 227. a gas sensor; 228. an air extraction assembly; 311. a support frame; 312. an outer shell plate; 313. a peristaltic pump; 314. a liquid pumping pipe; 315. a liquid outlet pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-9, the present invention provides a technical solution: the utility model provides a control cloud platform, including explosion-proof experiment cabinet 1, the inside of explosion-proof experiment cabinet 1 is provided with first reaction unit 2 and second reaction unit 3, first reaction unit 2 sets up the front end at second reaction unit 3, first reaction unit 2 includes reaction vessel 21 and gas collection device 22, the top of reaction vessel 21 and the bottom swing joint of gas collection device 22, gas collection device 22 includes apron 221, touch sensor 225 and gas collecting bottle 226, the bottom of apron 221 and the top fixed connection of reaction vessel 21, the top fixed connection of apron 221 has reaction cover 222, the top fixed connection of apron 221 has gas transmission pipe 224, gas transmission pipe 224's top fixedly connected with subassembly 228, the top of subassembly 228 and the bottom swing joint of gas collecting bottle 226 bleed, gas collecting bottle 226 sets up the bottom at reaction cover 222, the bottom of gas collecting bottle 226 is provided with gas sensor 227, annular 223 has been seted up at the top of apron 221, one side fixed connection of annular has touch sensor 225.

The explosion-proof experiment cabinet 1 comprises a cabinet body 11 and a supporting experiment table 14, the bottom of the inner side of the cabinet body 11 is fixedly connected with the bottom of the supporting experiment table 14, an experiment plate 15 is fixedly connected with the top of the supporting experiment table 14, the cabinet body 11 is made of a stainless steel plate material for pressure-bearing equipment, and the inner wall of the cabinet body is a solid physicochemical plate with corrosion resistance, antibiosis, ultraviolet resistance and other performances.

The top front end of laboratory glassware 15 is provided with pressure plate 17, and reaction vessel 21 sets up at the top of pressure plate 17, and the bottom of pressure plate 17 is provided with differential pressure sensor 18, and the bottom of cabinet body 11 evenly is provided with a plurality of sill bar 16, and reaction vessel 21 is used for placing at the top of pressure plate 17, and differential pressure sensor 18 transmits the weight of reaction vessel 21 to remote monitoring platform in real time.

The top front end of laboratory sheet 15 is provided with pressure plate 17, and the bottom of pressure plate 17 is provided with differential pressure sensor 18, and the bottom of cabinet body 11 evenly is provided with a plurality of foundation 16, and foundation 16 plays the supporting role, avoids the possible corrosion means of liquid on the laboratory bench.

The front end of the cabinet body 11 is provided with a front end door 12, the rear end of the cabinet body 11 is provided with a rear end door 13, and the front end door 12 and the rear end door 13 can be opened for operation.

The top fixedly connected with alarm device 19 of the cabinet body 11, the top inboard of the cabinet body 11 is provided with camera device 10, and alarm device 19 is automatic alarm when taking place chemical reagent and revealing, reminds the experimenter to handle, avoids appearing a large amount of weeping circumstances, and camera device 10 makes things convenient for the experimenter to observe and operate with the all-round picture real-time transmission to the remote monitoring platform in the cabinet body 11 reaction vessel 21 of the experimentation.

The second reaction device 3 comprises a transfer device 31, a reaction flask 32 and a magnetic stirrer 33, wherein the magnetic stirrer 33 is uniformly arranged at the top of the experiment board 15, the number of the magnetic stirrers 33 is three, the bottom of the reaction flask 32 is movably connected with the top of the magnetic stirrer 33, and the magnetic stirrer 33 performs corresponding operation on the reaction flask 32 needing to be heated or stirred, so that the reaction is promoted to be performed.

The transfer device 31 comprises a support frame 311 and a shell plate 312, the bottom of the support frame 311 is fixedly connected with the top of the experimental plate 15, the top of the support frame 311 is movably connected with the two ends of the shell plate 312, and the support frame 311 plays a role in supporting the top shell plate 312 and the internal peristaltic pump 313.

The inside of outer shell plate 312 is provided with a plurality of peristaltic pump 313, and the quantity of peristaltic pump 313 is two, and peristaltic pump 313's bottom fixedly connected with liquid suction pipe 314, one side fixedly connected with drain pipe 315 of peristaltic pump 313, and peristaltic pump 313 can shift the solution in the reaction flask 32 through liquid suction pipe 314 and drain pipe 315 automatically.

The bottom of the liquid pumping pipe 314 is movably connected with the top of the reaction bottle 32, the bottom of the liquid outlet pipe 315 is movably connected with the top of the reaction bottle 32, the liquid pumping pipe 314 is connected with one reaction bottle 32, and the liquid outlet pipe 315 is connected with the other reaction bottle 32, so that automatic liquid transferring is realized.

The working principle of the embodiment is as follows: when the device is used, the explosion-proof experimental cabinet 1 is placed on an experimental bench, the front end door 12 is opened, chemical reagents required to react are added into the reaction container 21, the gas collecting device 22 at the top is covered on the reaction container 21, the reaction container 21 is placed on the pressure plate 17 at the top of the experimental plate 15, the bottom of the pressure plate 17 is provided with a differential pressure sensor 18, then the chemical reagents are placed into the corresponding three reaction bottles 32 according to the chemical experiment requirements, each reaction bottle 32 is placed on the magnetic stirrer 33 at the top of the experimental plate 15, the liquid pumping pipe 314 and the liquid discharging pipe 315 at the bottom of the peristaltic pump 313 and the top ends of the corresponding three reaction bottles 32 are set by an experimenter through a remote monitoring platform, specifically, the stirring speed and the time of the magnetic stirrer 33, the reagent amount pumped by the liquid pumping pipe 314 and the like are set, after the parameters are adjusted, the chemical reagents in the reaction container 21 and the reaction bottles 32 begin to react, the camera device 10 at the top of the cabinet 11 transmits the omnibearing picture in the reaction container 21 of the cabinet 11 to the remote monitoring platform in real time in the experimental process, which is convenient for the experimenter to observe and operate, the gas reacted in the reaction container 21 is rapidly transmitted to the top gas collecting bottle 226 by the air pumping component 228 through the top cover plate 221 and the gas transmission pipe 224, the gas is continuously collected in the gas collecting bottle 226, the gas sensor 227 is arranged at the bottom of the gas collecting bottle 226, the gas sensor 227 can detect the gas, the gas sensor 227 detects the smell of the gas generated by the reaction and transmits the smell to the remote monitoring platform, the weight of the reaction container 21 is continuously reduced after the reaction, the differential pressure sensor 18 at the bottom of the reaction container 21 transmits the pressure in the reaction container 21 to the remote monitoring platform in real time, and the experimenter can automatically obtain the reaction data according to the pressure difference between the beginning and the end, when a small amount of chemical reagent in the reaction container 21 overflows, the reagent touches the touch sensor 225 through the annular groove 223, the touch sensor 225 timely transmits information to a remote monitoring platform, an experimenter can sound an alarm device 19 at the top of the cabinet 11 for remote operation to remind the experimenter to process and avoid reagent leakage, the transfer device 31 orderly carries out quantitative accurate liquid transfer in the chemical reaction process to mix the chemical reagent, the magnetic stirrer 33 correspondingly operates the reaction container 21 needing to be heated or stirred to promote reaction, the chemical experiment monitoring cloud platform for the chemical laboratory is characterized in that the experimenter can transmit information such as smell, liquid leakage and pressure generated by reaction to the remote monitoring platform through an explosion-proof experimental cabinet 1 realizing the function of monitoring the cloud platform, the experimenter can know the chemical reaction condition in real time and make corresponding operation through the remote monitoring platform, the gas sensor 227, the touch sensor 225 and the differential pressure sensor 18 can automatically and orderly transmit information such as smell, liquid leakage and pressure generated by reaction to the remote monitoring platform, a real-time picture is transmitted to the remote monitoring platform through the camera device 10, the experimenter can automatically and accurately transfer the chemical reagent to the remote monitoring platform in order to avoid harm to the automatic monitoring platform when the experimenter observes the chemical reaction container 21.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention.

Claims

1. The utility model provides a control cloud platform, includes explosion-proof experiment cabinet (1), the inside of explosion-proof experiment cabinet (1) is provided with first reaction unit (2) and second reaction unit (3), first reaction unit (2) set up the front end at second reaction unit (3), its characterized in that: first reaction unit (2) are including reaction vessel (21) and gas collection device (22), the top of reaction vessel (21) and the bottom swing joint of gas collection device (22), gas collection device (22) are including apron (221), touch sensor (225) and gas receiving flask (226), the bottom of apron (221) and the top fixed connection of reaction vessel (21), the top fixed connection of apron (221) has reaction cover (222), the gaseous defeated pipe (224) of top fixedly connected with of apron (221), the top fixedly connected with of gaseous defeated pipe (224) subassembly (228) of bleeding, the top of bleeding subassembly (228) and the bottom swing joint of gas receiving flask (226), gas receiving flask (226) set up the bottom at reaction cover (222), the bottom of gas receiving flask (226) is provided with gas sensor (227), annular groove (223) have been seted up at the top of apron (221), one side fixedly connected with touch sensor (225) of annular groove (223).

2. The monitoring cloud platform of claim 1, wherein: explosion-proof experiment cabinet (1) is including the cabinet body (11) and support laboratory bench (14), the inboard bottom of the cabinet body (11) and the bottom fixed connection who supports laboratory bench (14), the top fixedly connected with laboratory panel (15) of support laboratory bench (14).

3. The monitoring cloud platform of claim 2, wherein: the top front end of experiment board (15) is provided with pressure plate (17), reaction vessel (21) set up the top at pressure plate (17), the bottom of pressure plate (17) is provided with differential pressure sensor (18), the bottom of the cabinet body (11) evenly is provided with a plurality of sill pillar (16).

4. The monitoring cloud platform of claim 2, wherein: the top front end of experiment board (15) is provided with pressure plate (17), the bottom of pressure plate (17) is provided with differential pressure sensor (18), the bottom of the cabinet body (11) evenly is provided with a plurality of foundation (16).

5. The monitoring cloud platform of claim 2, wherein: the front end of the cabinet body (11) is provided with a front end door (12), and the rear end of the cabinet body (11) is provided with a rear end door (13).

6. The monitoring cloud platform of claim 2, wherein: the top of the cabinet body (11) is fixedly connected with an alarm device (19), and the inner side of the top of the cabinet body (11) is provided with a camera device (10).

7. The monitoring cloud platform of claim 1, wherein: second reaction unit (3) are including transfer device (31), reaction flask (32) and magnetic stirrers (33), magnetic stirrers (33) evenly set up the top at laboratory sheet (15), just the quantity of magnetic stirrers (33) is three, the bottom of reaction flask (32) and the top swing joint of magnetic stirrers (33).

8. The monitoring cloud platform of claim 7, wherein: the transfer device (31) comprises a support frame (311) and a shell plate (312), the bottom of the support frame (311) is fixedly connected with the top of the experiment plate (15), and the top of the support frame (311) is movably connected with two ends of the shell plate (312).

9. The monitoring cloud platform of claim 8, wherein: the inside of shell board (312) is provided with a plurality of peristaltic pump (313), just the quantity of peristaltic pump (313) is two, the bottom fixedly connected with liquid suction pipe (314) of peristaltic pump (313), one side fixedly connected with drain pipe (315) of peristaltic pump (313).

10. The monitoring cloud platform of claim 9, wherein: the bottom of liquid suction pipe (314) and the top swing joint of reaction bottle (32), the bottom of drain pipe (315) and the top swing joint of reaction bottle (32).