CN214474574U

CN214474574U - Intelligent carbon capture remote monitoring device based on Internet of things technology

Info

Publication number: CN214474574U
Application number: CN202121083411.3U
Authority: CN
Inventors: 鞠新国; 孙锋; 徐宏飞; 李欣荣; 韩元剑; 顾迪; 施玉彬; 马守权; 唐亚洲
Original assignee: Jiangsu Shangweis Environmental Technology Co ltd
Current assignee: Jiangsu Sunvis Environmental Technology Co ltd
Priority date: 2021-05-20
Filing date: 2021-05-20
Publication date: 2021-10-22
Anticipated expiration: 2031-05-20

Abstract

The utility model discloses an intelligence carbon entrapment remote monitoring device based on internet of things, including carbon entrapment device, gas filter and collection device, intercommunication intake pipe, blast pipe and exhaust pipe on the carbon entrapment device, rigid coupling monitoring device on the blast pipe, monitoring device includes the ring body, the annular is seted up to the ring body bottom surface. The utility model discloses be provided with the monitoring subassembly, when the clean gas passes through in the ring body, the infrared ray shines in the filter, and the filter only allows the light of a certain specific wavelength of infrared ray to pass through, and this light shines on the light flux detector, and the received light flux of light flux detector can reflect the gaseous concentration of being surveyed in the environment, later with measured data through the GPRS module transmission to terminal equipment, can realize long-range real-time test data monitoring, degree of automation is high, and practical value is high, the utility model discloses set up collection device, can retrieve the carbon dioxide in the waste gas, do benefit to the reutilization, save the resource.

Description

Intelligent carbon capture remote monitoring device based on Internet of things technology

Technical Field

The utility model relates to a carbon entrapment technical field specifically is an intelligence carbon entrapment remote monitoring device based on internet of things.

Background

Carbon Capture and Storage (CCS, also known as Carbon Capture and sequestration, Carbon collection and Storage, etc.) refers to a technique for collecting Carbon dioxide (CO 2) produced by large power plants and storing it in various ways to avoid its emission into the atmosphere. The technology is considered as the most economical and feasible method for reducing greenhouse gas emission and slowing down global warming in the future on a large scale, mainly comprises a flue gas pretreatment system, an absorption and regeneration system, a compression drying system, a refrigeration liquefaction system and the like, carbon capture equipment is widely applied to factory areas such as coal-fired power plants and the like, the existing carbon capture equipment sucks waste gas into the equipment from an air inlet, clean gas is discharged from an air outlet after processes such as vulcanization, liquid filtration and the like, and waste gas containing carbon dioxide and impurities is discharged from an exhaust port, and the existing carbon capture equipment has the following defects in use: the waste gas generated by carbon capture contains a large amount of carbon dioxide, the waste gas can generate carbon dioxide when being intensively treated, and the industrial application of the carbon dioxide is very wide: in the machine foundry industry, carbon dioxide is an additive; in the metal smelting industry, carbon dioxide is a quality stabilizer; in the ceramic enameling industry, carbon dioxide is the fixing agent; in the beverage beer industry, carbon dioxide is an additive for promoting digestion and appetite, and thus, the waste of carbon dioxide is caused. In addition carbon capture equipment during operation need detect exhaust clean gas, ensures that its carbon dioxide concentration is less than certain numerical value, mainly uses the detector periodic detection at present, unable real-time detection, and the data detected need the manual work to read simultaneously, extravagant manpower on the one hand, and the unable real-time supervision of on the other hand is unfavorable for the use.

Therefore, an intelligent carbon capture remote monitoring device based on the internet of things technology is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an intelligence carbon entrapment remote monitoring device based on internet of things to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an intelligence carbon entrapment remote monitoring device based on internet of things, includes carbon entrapment device, gas filter jar and collection device, intercommunication intake pipe, blast pipe and exhaust pipe on the carbon entrapment device, rigid coupling monitoring device on the blast pipe, monitoring device includes the ring body, the annular is seted up to the ring bottom surface, the annular cup joints at the blast pipe tip, ring inside wall rigid coupling infrared lamp, the notch is seted up to ring inside wall principle infrared lamp position, rigid coupling optical filter and light flux detector in the notch, the inside rigid coupling GPRS module of ring body, the optical filter is located position between infrared lamp and the light flux detector, the GPRS module is connected to the light flux detector electricity.

Preferably, the gas filtering tank comprises a tank body, a filtering cavity is formed in the tank body, a plurality of filter plates are fixedly connected in the filtering cavity, the top end of the tank body is communicated with a waste gas inlet and a carbon dioxide outlet, the carbon dioxide outlet is communicated with the end part of a second gas pipe, the waste gas pipe is communicated with one end of a first gas pipe, and the other end of the first gas pipe is communicated with the waste gas inlet.

Preferably, the collecting device comprises a shell, a sealing cover is fixedly connected to the shell, a plurality of partition plates are fixedly connected to the inside of the shell, a plurality of chambers are formed between the inside of the shell and the plurality of partition plates, and the chambers are filled with filter gas liquid.

Preferably, a plurality of flange pipes of sealed lid top surface rigid coupling, it is a plurality of flange pipe intercommunication cavity, flange pipe top flange joint gas collecting bottle, the inside bottom surface rigid coupling carbon dioxide pipe of casing, a plurality of air cocks of carbon dioxide pipe surface intercommunication, casing lateral wall rigid coupling carbon dioxide import, carbon dioxide import intercommunication carbon dioxide pipe, carbon dioxide import intercommunication second trachea.

Preferably, a plurality of screw thread through-holes are opened to the annular position to the ring body lateral wall, and are a plurality of screw thread through-hole threaded connection a plurality of locking bolts, locking bolt tip rigid coupling has rubber cushion and contacts the exhaust pipe lateral wall.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses be provided with the monitoring subassembly, when the clean gas passes through in the ring body, the infrared ray shines in the filter, and the filter only allows the light of a certain specific wavelength of infrared ray to pass through, and this light shines on the light flux detector, and the received light flux of light flux detector can reflect the gaseous concentration of being surveyed in the environment, later with measured data through the GPRS module transmission to terminal equipment, can realize long-range real-time test data monitoring, degree of automation is high, and practical value is high, the utility model discloses set up collection device, can retrieve the carbon dioxide in the waste gas, do benefit to the reutilization, save the resource.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged structural diagram of the monitoring device of the present invention;

fig. 3 is an enlarged structure diagram of the structure of the filter tank and the collecting device of the present invention.

In the figure: the device comprises a carbon trapping device 1, a monitoring device 2, a filter tank 3, a collecting device 4, a first gas pipe 5, a second gas pipe 6, a gas inlet pipe 11, a gas outlet pipe 12, a waste gas pipe 13, a ring body 21, a ring groove 22, an infrared lamp 23, a notch 24, a filter lens 25, a luminous flux detector 26, a GPRS module 27, a threaded through hole 28, a locking bolt 29, a tank body 31, a filter cavity 32, a waste gas inlet 33, a filter plate 34, a carbon dioxide outlet 35, a shell 41, a sealing cover 42, a partition plate 43, a cavity 44, a gas filtering liquid 45, a carbon dioxide pipe 46, a gas nozzle 47, a flange pipe 48, a gas collecting bottle 49 and a carbon dioxide inlet 410.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: the utility model provides an intelligence carbon entrapment remote monitoring device based on internet of things, includes carbon entrapment device 1, canister 3 and collection device 4, intercommunication intake pipe 11, blast pipe 12 and exhaust pipe 13 on the carbon entrapment device 1, and when using, waste gas enters into carbon complementary collection device 1 through intake pipe 11, and later clean gas is discharged from blast pipe 12, and the waste gas that contains impurity and carbon dioxide is discharged from exhaust pipe 13.

Referring to fig. 3, the canister 3 includes a canister body 31, a filter chamber 32 is formed in the canister body 31, a plurality of filter plates 34 are fixedly connected in the filter chamber 32, a top end of the canister body 31 is communicated with a waste gas inlet 33, a bottom end of the canister body is communicated with a carbon dioxide outlet 35, the carbon dioxide outlet 35 is communicated with an end of the second gas pipe 6, the waste gas pipe 13 is communicated with one end of the first gas pipe 5, the other end of the first gas pipe 5 is communicated with the waste gas inlet 33, and waste gas containing impurities and carbon dioxide enters the canister 3 from the first gas pipe 5 and is discharged from the carbon dioxide outlet 35 after being filtered by the filter plates 34.

Referring to fig. 3, the collecting device 4 includes a housing 41, a sealing cover 42 is fixedly connected to the housing 41, a plurality of partition plates 43 are fixedly connected to the interior of the housing 41, a plurality of chambers 44 are formed between the interior of the housing 41 and the plurality of partition plates 43, a gas-filtering liquid 45 is filled in the chambers 44, a plurality of flange pipes 48 are fixedly connected to the top surface of the sealing cover 42, the plurality of flange pipes 48 are communicated with the chambers 44, a gas collecting bottle 49 is connected to the top end of the flange pipe 48, a carbon dioxide pipe 46 is fixedly connected to the bottom surface of the interior of the housing 41, a plurality of nozzles 47 are communicated to the surface of the carbon dioxide pipe 46, a carbon dioxide inlet 410 is fixedly connected to the outer side wall of the housing 41, the carbon dioxide inlet 410 is communicated with the carbon dioxide pipe 46, the carbon dioxide inlet 410 is communicated with the second gas pipe 6, the carbon dioxide waste gas is discharged into the collecting device 4 through the second gas pipe 6, water-soluble impurities are filtered by the filtering liquid 45, and then enter the gas collecting bottle 49 to collect the carbon dioxide, is favorable for secondary utilization and saves resources.

Referring to fig. 1-2, a monitoring device 2 is fixedly connected to an exhaust pipe 12, the monitoring device 2 includes a ring body 21, a ring groove 22 is formed on a bottom surface of the ring body 21, the ring groove 22 is sleeved on an end portion of the exhaust pipe 12, an infrared lamp 23 is fixedly connected to an inner side wall of the ring body 21, a notch 24 is formed in the inner side wall of the ring body 21 according to the position of the infrared lamp 23, a filter 25 and a light flux detector 26 are fixedly connected to an inside of the notch 24, a GPRS module 27 is fixedly connected to the inside of the ring body 21, the filter 25 is electrically connected to the GPRS module 26, when clean gas passes through the ring body 21, the infrared filter 25 is irradiated to the inside, the filter 25 only allows light of a specific wavelength of infrared rays to pass through, the light is irradiated to the light flux detector 26, the light flux received by the light flux detector 26 can reflect a concentration of the gas to be measured in an environment, and then the measured data is transmitted to a terminal device through the GPRS module 27, the remote real-time test data monitoring can be realized, the automation degree is high, and the practical value is high.

Referring to fig. 2, a plurality of threaded through holes 28 are formed in the outer side wall of the ring body 21 at positions corresponding to the ring grooves 22, the threaded through holes 28 are in threaded connection with a plurality of locking bolts 29, rubber pads are fixedly connected to the end portions of the locking bolts 29 and contact the side wall of the exhaust pipe 12, and the monitoring device 2 can be detached by detaching the locking bolts 29, so that maintenance is facilitated.

The working principle is as follows: the utility model discloses when using, waste gas enters into carbon complement device 1 through intake pipe 11, later clean gas is discharged from blast pipe 12, the waste gas that contains impurity and carbon dioxide is discharged from exhaust gas pipe 13 and is got into to canister 3 through first trachea 5, filter the back through filter plate 34 and discharge by carbon dioxide export 35, later carbon dioxide waste gas is discharged to collection device 4 in through second trachea 6, later filter out water-soluble impurity through filtrate 45, later get into in gas collecting bottle 49, can collect carbon dioxide. The utility model discloses be provided with monitoring subassembly 2, when clean gas passes through in the ring body 21, infrared ray shines in the optical filter 25, and optical filter 25 only allows the light of a certain specific wavelength of infrared ray to pass through, and this light shines on light flux detector 26, and the light flux that light flux detector 26 received can reflect the gaseous concentration of being surveyed in the environment, later with measured data through GPRS module 27 transmission to terminal equipment, can realize long-range real-time test data monitoring, degree of automation is high, and practical value is high, the utility model discloses set up collection device, can retrieve the carbon dioxide in the waste gas, do benefit to the reutilization, save the resource.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an intelligence carbon entrapment remote monitoring device based on internet of things, includes carbon entrapment device (1), filter gas jar (3) and collection device (4), intercommunication intake pipe (11), blast pipe (12) and exhaust pipe (13) on carbon entrapment device (1), its characterized in that:

the exhaust pipe (12) is fixedly connected with a monitoring device (2), the monitoring device (2) comprises a ring body (21), a ring groove (22) is formed in the bottom surface of the ring body (21), the ring groove (22) is connected to the end portion of the exhaust pipe (12) in a sleeved mode, an infrared lamp (23) is fixedly connected to the inner side wall of the ring body (21), a notch (24) is formed in the position of the infrared lamp (23) according to the principle of the inner side wall of the ring body (21), a filter lens (25) and a luminous flux detector (26) are fixedly connected into the notch (24), and a GPRS module (27) is fixedly connected into the ring body (21);

the filter (25) is positioned between the infrared lamp (23) and the luminous flux detector (26), and the luminous flux detector (26) is electrically connected with the GPRS module (27).

2. The intelligent carbon capture remote monitoring device based on the internet of things technology as claimed in claim 1, wherein: the filter tank (3) is including a jar body (31), set up filter chamber (32) in jar body (31), a plurality of filter plates of rigid coupling (34) in filter chamber (32), jar body (31) top intercommunication waste gas import (33), bottom intercommunication carbon dioxide export (35), carbon dioxide export (35) intercommunication second trachea (6) tip, waste gas pipe (13) intercommunication first trachea (5) one end, first trachea (5) other end intercommunication waste gas import (33).

3. The intelligent carbon capture remote monitoring device based on the internet of things technology as claimed in claim 1, wherein: the collecting device (4) comprises a shell (41), a sealing cover (42) is fixedly connected to the shell (41), a plurality of partition plates (43) are fixedly connected to the inside of the shell (41), a plurality of cavities (44) are formed between the inside of the shell (41) and the plurality of partition plates (43), and filter liquid (45) is filled in the cavities (44).

4. The intelligent carbon capture remote monitoring device based on the internet of things technology as claimed in claim 3, wherein: sealed lid (42) a plurality of flange pipes of top surface rigid coupling (48), it is a plurality of flange pipe (48) intercommunication cavity (44), flange pipe (48) top flange joint gas collecting bottle (49), casing (41) inside bottom surface rigid coupling carbon dioxide pipe (46), a plurality of air cocks (47) of carbon dioxide pipe (46) surface intercommunication, casing (41) lateral wall rigid coupling carbon dioxide import (410), carbon dioxide import (410) intercommunication carbon dioxide pipe (46), carbon dioxide import (410) intercommunication second trachea (6).

5. The intelligent carbon capture remote monitoring device based on the internet of things technology as claimed in claim 1, wherein: a plurality of screw through-holes (28) are seted up to ring body (21) lateral wall to annular (22) position, and are a plurality of screw through-hole (28) a plurality of locking bolt (29) of threaded connection, locking bolt (29) tip rigid coupling has rubber cushion and contact blast pipe (12) lateral wall.