CN217278224U

CN217278224U - Carbon dioxide emission monitoring facilities

Info

Publication number: CN217278224U
Application number: CN202220717315.8U
Authority: CN
Inventors: 梁超; 张艺; 安杉; 蒙仲举; 党晓宏
Original assignee: Inner Mongolia Chaoyi Carbon Resources Technology Development Co Ltd
Current assignee: Inner Mongolia Chaoyi Carbon Resources Technology Development Co Ltd
Priority date: 2022-03-30
Filing date: 2022-03-30
Publication date: 2022-08-23
Anticipated expiration: 2032-03-30

Abstract

The utility model relates to a monitoring facilities technical field, concretely relates to carbon dioxide emission monitoring facilities, including the rectangle case, the intermediate position department of rectangle incasement bottom surface has linked firmly the storage shell, the intermediate position department intercommunication at storage shell top is fixed with connecting pipe one. The utility model discloses in, be fixed with air flowmeter through the one end intercommunication at automatically controlled valve one, and utilize air flowmeter to measure out the volume flow who carries gas from two departments of connecting pipe, and through opening automatically controlled valve one, thereby utilize connecting pipe one with the inside of gas transportation to the reservoir shell, close automatically controlled valve one after carrying the gas of suitable volume flow, and utilize the gas detection appearance to detect out the content of carbon dioxide in the reservoir shell internal gas, thereby can know the proportion that occupies of carbon dioxide in certain volume flow's the gas, and then can know the approximate content of carbon dioxide in the internal gas through air flowmeter fast, make this carbon dioxide discharge monitoring facilities can monitor out the emission of carbon dioxide fast.

Description

Carbon dioxide emission monitoring facilities

Technical Field

The utility model relates to a monitoring facilities technical field, concretely relates to carbon dioxide emission monitoring facilities.

Background

Carbon dioxide emissions refer to the average greenhouse gas emissions generated during the production, transportation, use, and recovery of a product. The dynamic carbon emission refers to the amount of greenhouse gas discharged by each unit of goods, different dynamic carbon emission amounts exist among batches of the same product, a large amount of waste gas can be discharged when some factories produce the product, and the waste gas contains a large amount of carbon dioxide gas, so that the carbon dioxide emission amount of the factories needs to be monitored in real time, but the existing carbon dioxide emission monitoring equipment is complex in structure, inconvenient to use and operate and inaccurate in detection structure.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: in order to solve the problems that the existing carbon dioxide emission monitoring equipment is complex in structure, inconvenient to use and operate and inaccurate in detection structure, the carbon dioxide emission monitoring equipment is provided.

The purpose of the utility model can be realized by the following technical scheme:

a carbon dioxide emission monitoring device comprises a rectangular box, wherein a storage shell is fixedly connected to the middle position of the inner bottom surface of the rectangular box, a first connecting pipe is fixedly communicated with the middle position of the top of the storage shell, a first electric control valve is fixedly connected to one end of the first connecting pipe, an air flow meter is fixedly connected to one end of the first electric control valve, a second connecting pipe is fixedly connected to one end of the air flow meter, one end of the second connecting pipe penetrates through the side wall of the rectangular box and extends to the outer side of the rectangular box, a rectangular hole is formed in the middle position of one side of the storage shell, a gas detector is fixedly connected to the inner side wall of the rectangular hole, a control screen is fixedly connected to the middle position of the top of one side of the rectangular box, when the carbon dioxide emission monitoring device is used, the volume flow of gas conveyed from the second connecting pipe is measured by the air flow meter, and the first electric control valve is opened, so that the gas is conveyed to the inside of the storage shell by the first connecting pipe, the first electric control valve is closed after the gas with proper volume flow is conveyed, and the content of the carbon dioxide in the gas in the storage shell is detected by using the gas detector, so that the proportion occupied by the carbon dioxide in the gas with certain volume flow can be known, the approximate content of the carbon dioxide in the gas passing through the air flow meter can be quickly known, the emission amount of the carbon dioxide can be quickly monitored by the carbon dioxide emission monitoring equipment, and the control screen is used for conveniently controlling and operating the carbon dioxide emission monitoring equipment.

The gas storage device is characterized in that a second electric control valve is fixedly communicated with the middle position of the bottom of the other side of the storage shell, a third connecting pipe is fixedly communicated with one end of the second electric control valve, one end of the third connecting pipe penetrates through the side wall of the rectangular box and extends to the outer side of the rectangular box, and the second electric control valve and the third connecting pipe are used for conveniently discharging gas in the storage shell.

Further lie in, the outside of two one ends of connecting pipe has linked firmly screwed pipe two, the inserting groove has been seted up in the outside of screwed pipe two, the inside of inserting groove one end is provided with the pipe, and the pipe is relative with the one end of connecting pipe two, the inside of pipe has linked firmly filtration membrane, utilizes filtration membrane to filter foreign matter among the conveying gas, avoids the foreign matter to get into inside the storage shell.

Further lie in, the connection breach has all been seted up to two inside walls of the inserting groove other end, the lateral wall of pipe has linked firmly the connecting plate, and connecting plate and inserting groove sliding connection utilize the connection breach to be convenient for take out the connecting plate and move to be convenient for take out filtration membrane and change.

Further, the outer side of the second spiral pipe is connected with the first spiral pipe in a screwing mode, one end of the second spiral pipe is fixedly connected with a ring, the outer diameter of the ring is the same as that of the first spiral pipe, the first spiral pipe is used for conveniently shielding and limiting a connecting notch, the ring is prevented from moving when in use, and the first spiral pipe is limited by the ring.

And a first pipe joint is fixedly communicated with one end of the third connecting pipe, and a second pipe joint is fixedly communicated with the middle position of one side of the circular ring.

The first connecting pipe, the second connecting pipe and the third connecting pipe have the same outer diameter, and the first connecting pipe, the second connecting pipe and the third connecting pipe have the same inner diameter.

The utility model has the advantages that:

1. the air flow meter is fixedly communicated with one end of the first electric control valve, the volume flow of the gas conveyed from the second connecting pipe is measured by the air flow meter, the first electric control valve is opened, the gas is conveyed to the inside of the storage shell by the first connecting pipe, the first electric control valve is closed after the gas with proper volume flow is conveyed, the content of the carbon dioxide in the gas in the storage shell is detected by the gas detector, the proportion occupied by the carbon dioxide in the gas with certain volume flow can be known, the approximate content of the carbon dioxide in the gas passing through the inside of the air flow meter can be rapidly known, and the emission amount of the carbon dioxide can be rapidly monitored by the carbon dioxide emission monitoring device.

Drawings

The present invention will be further described with reference to the accompanying drawings.

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

FIG. 2 is a schematic view showing the positional relationship between the gas detector and the storage case of the present invention;

FIG. 3 is a schematic view of the structure of the storage case of the present invention;

fig. 4 is a schematic diagram of the position relationship between the second middle spiral tube and the circular tube.

In the figure: 100. a rectangular box; 110. a control screen; 120. a gas detector; 130. a storage shell; 131. a rectangular hole; 140. a first connecting pipe; 141. a first electric control valve; 142. an air flow meter; 143. a second connecting pipe; 150. a second electric control valve; 151. a third connecting pipe; 152. a pipe joint I; 160. a first spiral pipe; 170. a second spiral pipe; 171. inserting grooves; 172. a connecting gap; 173. a circular ring; 180. a circular tube; 181. filtering the membrane; 182. a connecting plate; 200. and a pipe joint II.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-4, a carbon dioxide emission monitoring device includes a rectangular box 100, a storage case 130 is fixedly connected to a middle position of an inner bottom surface of the rectangular box 100, a first connection pipe 140 is fixedly connected to a middle position of a top of the storage case 130, a first electric control valve 141 is fixedly connected to one end of the first connection pipe 140, an air flow meter 142 is fixedly connected to one end of the first electric control valve 141, a second connection pipe 143 is fixedly connected to one end of the air flow meter 142, one end of the second connection pipe 143 penetrates through a side wall of the rectangular box 100 and extends to an outer side of the rectangular box 100, a rectangular hole 131 is formed in a middle position of one side of the storage case 130, a gas detector 120 is fixedly connected to an inner side wall of the rectangular hole 131, a control panel 110 is fixedly connected to a middle position of a top of one side of the rectangular box 100, when the carbon dioxide emission monitoring device is used, a volume flow of gas delivered from the second connection pipe 143 is measured by the air flow meter 142, and the first electric control valve 141 is opened, therefore, the first connecting pipe 140 is used for conveying the gas to the inside of the storage shell 130, the first electric control valve 141 is closed after the gas with proper volume flow is conveyed, the content of the carbon dioxide in the gas in the storage shell 130 is detected by the gas detector 120, the proportion occupied by the carbon dioxide in the gas with certain volume flow can be known, the approximate content of the carbon dioxide in the gas passing through the air flow meter 142 can be rapidly known, the emission amount of the carbon dioxide can be rapidly monitored by the carbon dioxide emission monitoring device, and the control screen 110 is used for conveniently controlling and operating the carbon dioxide emission monitoring device.

The middle position of the bottom of the other side of the storage shell 130 is fixedly communicated with an electric control valve II 150, one end of the electric control valve II 150 is fixedly communicated with a connecting pipe III 151, one end of the connecting pipe III 151 penetrates through the side wall of the rectangular box 100 and extends to the outer side of the rectangular box 100, the gas in the storage shell 130 is conveniently discharged by utilizing the electric control valve II 150 and the connecting pipe III 151, the outer side of one end of the connecting pipe II 143 is fixedly connected with a spiral pipe II 170, the outer side of the spiral pipe II 170 is provided with an insertion groove 171, the inner part of one end of the insertion groove 171 is provided with a round pipe 180, the round pipe 180 is opposite to one end of the connecting pipe II 143, the inner part of the round pipe 180 is fixedly connected with a filtering film 181, foreign matters in the conveying gas are filtered by utilizing the filtering film 181, the foreign matters are prevented from entering the storage shell 130, two inner side walls at the other end of the insertion groove 171 are both provided with connecting gaps 172, the outer side wall of the round pipe 180 is fixedly connected with a connecting plate 182, and the connecting plate 182 is connected with the insertion groove 171 in a sliding manner, the connection notch 172 is used to facilitate the pulling of the connection plate 182, thereby facilitating the removal and replacement of the filter membrane 181.

The outer side of the second spiral pipe 170 is connected with the first spiral pipe 160 in a screwing mode, one end of the second spiral pipe 170 is fixedly connected with the ring 173, the outer diameter of the ring 173 is the same as that of the first spiral pipe 160, the first spiral pipe 160 is used for conveniently shielding and limiting the connecting notch 172, the ring 173 is prevented from moving when in use, the ring 173 is used for limiting the first spiral pipe 160, one end of the third connecting pipe 151 is fixedly communicated with the first pipe connector 152, the middle position of one side of the ring 173 is fixedly communicated with the second pipe connector 200, the first connecting pipe 140, the second connecting pipe 143 and the third connecting pipe 151 are the same in outer diameter, and the first connecting pipe 140, the second connecting pipe 143 and the third connecting pipe 151 are the same in inner diameter.

The working principle is as follows: when the carbon dioxide emission monitoring device is used, the carbon dioxide emission monitoring device is placed at a proper position, the pipe joint II 200 is conveniently connected with the external gas transmission pipeline, so that the external gas transmission pipeline conveniently transmits gas to the inside of the connecting pipe II 143, the air flow meter 142 is used for metering the volume flow of the gas transmitted from the connecting pipe II 143, the electric control valve I141 is opened, so that the gas is transmitted to the inside of the storage shell 130 through the connecting pipe I140, the electric control valve I141 is closed after the gas with the proper volume flow is transmitted, the content of the carbon dioxide in the gas in the storage shell 130 is detected through the gas detector 120, the proportion occupied by the carbon dioxide in the gas with the certain volume flow can be known, the approximate content of the carbon dioxide in the gas passing through the air flow meter 142 can be rapidly known, and the carbon dioxide emission amount can be rapidly monitored by the carbon dioxide emission monitoring device, after the inside gaseous detection of storage shell 130 is accomplished, utilize pipe connector 152 to be convenient for to be connected with external pipeline of giving vent to anger to through opening two electric control valves 150, utilize two electric control valves 150, three 151 of connecting pipe and pipe connector 152 to be convenient for carry gas to the inside of external pipeline of giving vent to anger, and utilize filtration membrane 181 to filter the foreign matter in the conveying gas, avoid the foreign matter to get into inside the storage shell 130.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is illustrative and explanatory only, and various modifications, additions and substitutions as described for the specific embodiments described herein may be made by those skilled in the art without departing from the scope of the invention or exceeding the scope of the invention as defined in the claims.

Claims

1. A carbon dioxide emission monitoring device comprising a rectangular box (100), characterized in that, the middle position of the inner bottom surface of the rectangular box (100) is fixedly connected with a storage shell (130), a first connecting pipe (140) is fixedly communicated with the middle position of the top of the storage shell (130), one end of the first connecting pipe (140) is fixedly connected with a first electric control valve (141), one end of the first electric control valve (141) is fixedly communicated with an air flow meter (142), one end of the air flow meter (142) is fixedly connected with a second connecting pipe (143), one end of the second connecting pipe (143) penetrates through the side wall of the rectangular box (100) and extends to the outer side of the rectangular box (100), a rectangular hole (131) is arranged in the middle of one side of the storage shell (130), the inside wall of rectangle hole (131) has linked firmly gas detection appearance (120), the intermediate position department at rectangle case (100) one side top has linked firmly control screen (110).

2. The carbon dioxide emission monitoring device as recited in claim 1, wherein a second electrically controlled valve (150) is fixed to the bottom of the other side of the storage shell (130) at a middle position, a third connecting pipe (151) is fixed to one end of the second electrically controlled valve (150) in a communicating manner, and one end of the third connecting pipe (151) penetrates through the side wall of the rectangular box (100) and extends to the outside of the rectangular box (100).

3. The carbon dioxide emission monitoring device according to claim 1, wherein a second spiral pipe (170) is fixedly connected to an outer side of one end of the second connecting pipe (143), an insertion groove (171) is formed in an outer side of the second spiral pipe (170), a circular pipe (180) is arranged inside one end of the insertion groove (171), the circular pipe (180) is opposite to one end of the second connecting pipe (143), and a filtering film (181) is fixedly connected inside the circular pipe (180).

4. The carbon dioxide emission monitoring device according to claim 3, wherein the two inner side walls of the other end of the insertion groove (171) are both provided with a connection notch (172), the outer side wall of the circular tube (180) is fixedly connected with a connection plate (182), and the connection plate (182) is slidably connected with the insertion groove (171).

5. The carbon dioxide emission monitoring device according to claim 3, wherein the first screw pipe (160) is screwed to the outer side of the second screw pipe (170), one end of the second screw pipe (170) is fixedly connected with a circular ring (173), and the outer diameter of the circular ring (173) is the same as that of the first screw pipe (160).

6. The carbon dioxide emission monitoring device according to claim 2, wherein a first pipe joint (152) is connected and fixed to one end of the third connecting pipe (151), and a second pipe joint (200) is connected and fixed to a middle position on one side of the circular ring (173).

7. The carbon dioxide emission monitoring apparatus according to claim 1, wherein the first connecting pipe (140), the second connecting pipe (143), and the third connecting pipe (151) have the same outer diameter, and the first connecting pipe (140), the second connecting pipe (143), and the third connecting pipe (151) have the same inner diameter.