CN214751566U - Carbon emission monitoring management device with automatic benchmarking function - Google Patents

Abstract

The utility model discloses a carbon emission control management device with automatic benchmarking function, including base and inserted block, the lower extreme fixedly connected with stabilizer blade of base, and the inside of base has seted up the drainage groove, the top fixedly connected with cabinet body of base, and the inside of the cabinet body has seted up the seal groove, the right side fixedly connected with spring of inserted block, and the inserted block is located the inside of seal groove, the right side fixedly connected with door frame of spring, and the inside upper end fixedly connected with of door frame receive the box, the below of inserted block is provided with the heat dissipation fan, the below swing joint of receiving the box has the dodge gate, and the left side swing joint of dodge gate has the hinge. This carbon emission control management device with automatically, to mark function can detect carbon emission data, and the carbon emission standard numerical value in the accessible database carries out difference calculation and data contrast to real time monitoring's carbon emission data, can play the automatic effect to mark.

Description

Carbon emission monitoring management device with automatic benchmarking function

Technical Field

The utility model relates to a carbon emission control management device technical field specifically is a carbon emission control management device with automatic benchmarking function.

Background

The carbon emission of the society is one of the very important environmental protection indexes nowadays, and the phenomenon of global warming is one of the global hot spot problems, and the influence on human life is very serious, and the carbon dioxide discharged in human production life is one of the main causes of global warming, so the phenomenon of carbon emission is greatly managed, which is the important factor to be solved at present, and the carbon emission monitoring and managing equipment is generated due to transportation, and the equipment can monitor and manage the generated carbon dioxide in real time, can know the real-time emission value of the human to the carbon dioxide in real time, and accurately manage the carbon dioxide.

The existing carbon emission monitoring management device cabinet cannot perform benchmarking operation on monitored carbon emission data, so that equipment can only detect the carbon emission data when in use, the carbon emission data cannot pass through carbon emission standard values in a database, difference value calculation and data comparison are performed on the carbon emission data monitored in real time, automatic benchmarking effect cannot be achieved, so that when the data are displayed, other people cannot rapidly obtain specific standard-exceeding values, the waterproof and moistureproof performance of the device is limited, the structure is usually integrated, rapid installation and disassembly are not convenient, and temperature and humidity monitoring parts are not arranged, so that the use safety of the device cannot be effectively guaranteed, the use requirements of people cannot be well met, and technical innovation is performed on the basis of the existing carbon emission monitoring management device.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a carbon emission monitoring and managing device with an automatic benchmarking function, the problem that the existing carbon emission monitoring and managing device cabinet in the background art can not perform standard matching operation on the monitored carbon emission data is solved, when the device is used, only the carbon emission data can be detected, and the carbon emission standard value in the database can not be passed, the difference value calculation and the data comparison are carried out on the carbon emission data monitored in real time, the automatic target matching effect cannot be achieved, when the data is displayed, other people can not quickly obtain specific standard exceeding numerical values, the device has limited waterproof and moistureproof performance, the structure is usually integrated, the device is not convenient to quickly mount and dismount, and temperature and humidity monitoring parts are not arranged, therefore, the safety of the device in use can not be effectively guaranteed, and the use requirement of people can not be well met.

In order to achieve the above object, the utility model provides a following technical scheme: a carbon emission monitoring and management device with an automatic benchmarking function comprises a base and an insert block, wherein the lower end of the base is fixedly connected with support legs, a drainage groove is formed in the base, a cabinet body is fixedly connected to the upper portion of the base, a sealing groove is formed in the cabinet body, a spring is fixedly connected to the right side of the insert block, the insert block is located in the sealing groove, a door frame is fixedly connected to the right side of the spring, a receiving box is fixedly connected to the upper end of the interior of the door frame, a heat dissipation fan is arranged below the insert block, a movable door is movably connected to the lower portion of the receiving box, a hinge is movably connected to the left side of the movable door, a rainproof cover is fixedly connected to the upper portion of the cabinet body, a humidity sensor is movably connected to the rear side of the receiving box, a temperature sensor is arranged on the right side of the humidity sensor, and a monitoring meter is movably connected to the front end of the receiving box, and the output end of the receiving box is connected with a data collecting unit through a wire, the output end of the data collecting unit is connected with a data benchmarking module through a wire, the input end of the data benchmarking module is connected with an external big data unit through a wire, the output end of the data benchmarking module is connected with a data storage unit through a wire, and the output end of the data storage unit is connected with a data transmission unit through a wire.

Preferably, the upper surface of base and the lower surface of the cabinet body are closely attached to each other, and the support legs are symmetrical about the central axis of the cabinet body.

Preferably, the sealing grooves are symmetrical relative to the central axis of the cabinet body, and the inner dimension of the sealing grooves is matched with the outer dimension of the insertion block.

Preferably, the insert block forms an elastic structure with the door frame through the springs, and the springs are symmetrical with each other about a central axis of the door frame.

Preferably, the data benchmarking module comprises a data operation unit, a data comparison unit, a difference calculation unit and a data output unit, wherein the output end of the data operation unit is connected with the data comparison unit through a wire, the output end of the data comparison unit is connected with the difference calculation unit through a wire, and the output end of the difference calculation unit is connected with the data output unit through a wire.

Preferably, the data operation unit, the data comparison unit, the difference calculation unit and the data output unit are electrically connected in series through a wire, and the data comparison unit and the external big data unit are electrically connected in parallel through a wire.

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

1. the utility model discloses a setting of base, stabilizer blade, drainage groove, the cabinet body, seal groove for base and stabilizer blade are used for the support of carbon emission control management equipment to be fixed, thereby guarantee its stability when using, and the drainage groove cooperates the cabinet body and can prevent that liquid from invading the device inside, plays the effect of reducing the internal humidity of cabinet, and the seal groove of both sides is used for placing the position that the inserted block limited the door frame;

2. the utility model has the advantages that the inserting block is pressed to be inserted into the sealing groove by the inserting block, the spring, the door frame, the receiving box, the movable door and the hinge, the elastic force at the two sides interacts with each other under the elastic action of the spring when in installation, thereby ensuring that the door frame is limited to be fixed, the door frame is pushed to one side when in disassembly, the detachable structure between the inserting block and the spring is convenient for a user to carry out quick assembly and disassembly, the movable door is pulled to be opened under the action of the hinge, thereby carrying out local maintenance on the inner part of the cabinet body, the heat radiation fan, the rain cover, the temperature sensor, the humidity sensor and the monitoring meter are used for electrically connecting the heat radiation fan, the temperature sensor and the humidity sensor, when the internal temperature or the humidity rises, the heat radiation fan automatically starts to carry out heat radiation and humidity elimination on the inner part of the cabinet body, the rain cover plays the role of protecting the cabinet body, the temperature sensor and the humidity sensor respectively monitor the temperature and the humidity in the inner part of the cabinet body, the monitored data can be transmitted to the inside of the monitoring meter in real time, so that workers can observe the data conveniently, the safety factor of the carbon emission monitoring and managing equipment during use is improved, and the equipment needing to operate can be placed into the device for use during use of the device;

3. the utility model discloses a receiving box, the data collection unit, the data arithmetic unit, the data contrast unit, the difference calculation unit, the data output unit, outside big data unit, data storage unit and data transmission unit's setting, when making the device control the management to carbon emission, can be according to the data that the device control obtained, data transmission to receiving box in, data are carried out the benchmarking in data benchmarking module through the data collection unit and are calculated, through the data arithmetic unit, concentrate the operation to data, after the operation, with data transmission to the data contrast unit, outside big data unit simultaneously, can be with the carbon emission standard value data transmission in the database to carry out the automation benchmarking in the data contrast unit, data transmission after the automation benchmarking is to the difference calculation unit, after calculating the difference of two strands of data, with the data transmission who obtains of calculating to the data output unit, the data are transmitted to the data storage unit through the data output unit to be stored independently, and when a user needs to call the data out to read, the data can be transmitted from the data storage unit through the data transmission unit to be read.

Drawings

Fig. 1 is a schematic view of the internal structure of the present invention;

fig. 2 is a schematic view of a front view external development structure of the present invention;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1;

fig. 4 is an electrical schematic view of the present invention.

In the figure: 1. a base; 2. a support leg; 3. a drainage groove; 4. a cabinet body; 5. a sealing groove; 6. inserting a block; 7. a spring; 8. a door frame; 9. a heat dissipation fan; 10. a receiving box; 11. a movable door; 12. a hinge; 13. a rain cover; 14. a temperature sensor; 15. a humidity sensor; 16. a monitoring table; 17. a data collection unit; 18. a data benchmarking module; 1801. a data operation unit; 1802. a data comparison unit; 1803. a difference value calculation unit; 1804. a data output unit; 19. an external big data unit; 20. a data storage unit; 21. and a data transmission unit.

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. 1-4, the present invention provides a technical solution: a carbon emission monitoring and managing device with an automatic benchmarking function comprises a base 1 and an inserting block 6, wherein the lower end of the base 1 is fixedly connected with a support leg 2, and the interior of the base 1 is provided with a drainage groove 3, the upper surface of the base 1 is tightly attached with the lower surface of the cabinet body 4, the support legs 2 are symmetrical with respect to the central axis of the cabinet body 4, the base 1 and the support legs 2 are used for supporting and fixing the carbon emission monitoring and management equipment, thereby ensuring the stability of the cabinet when in use, the cabinet body 4 is fixedly connected above the base 1, the inside of the cabinet body 4 is provided with a sealing groove 5, the sealing grooves 5 are symmetrical relative to the central axis of the cabinet body 4, the inner size of the sealing groove 5 is matched with the outer size of the inserting block 6, the drainage groove 3 is matched with the cabinet body 4 to prevent liquid from invading into the device, so that the effect of reducing the humidity in the cabinet body 4 is achieved, and the sealing grooves 5 on the two sides are used for placing the inserting block 6 to limit the position of the door frame 8;

the right side of the insert block 6 is fixedly connected with a spring 7, the insert block 6 is positioned in the sealing groove 5, the insert block 6 forms an elastic structure with the door frame 8 through the spring 7, the springs 7 are symmetrical about the central axis of the door frame 8, the insert block 6 is inserted into the sealing groove 5 by pressing the insert block 6 during installation, under the elastic action of the spring 7, the elastic forces at two sides interact, so that the door frame 8 can be ensured to be fixed limitedly and pushed to one side during disassembly, the detachable structure between the two is convenient for a user to carry out quick installation and disassembly, the movable door 11 is pulled and opened under the action of a hinge 12, so that the inside of the cabinet body 4 can be maintained locally, the right side of the spring 7 is fixedly connected with the door frame 8, the upper end of the inside of the door frame 8 is fixedly connected with a receiving box 10, a heat dissipation fan 9 is arranged below the insert block 6, and the movable door 11 is movably connected below the receiving box 10, the left side of the movable door 11 is movably connected with a hinge 12, the upper part of the cabinet body 4 is fixedly connected with a rain cover 13, the rear side of the receiving box 10 is movably connected with a humidity sensor 15, the right side of the humidity sensor 15 is provided with a temperature sensor 14, the front end of the receiving box 10 is movably connected with a monitoring meter 16, and the output end of the receiving box 10 is connected with a data collecting unit 17 through a lead;

the output end of the data collection unit 17 is connected with the data benchmarking module 18 through a conducting wire, the input end of the data benchmarking module 18 is connected with the external big data unit 19 through a conducting wire, the data benchmarking module 18 comprises a data operation unit 1801, a data comparison unit 1802, a difference calculation unit 1803 and a data output unit 1804, the output end of the data operation unit 1801 is connected with the data comparison unit 1802 through a conducting wire, the output end of the data comparison unit 1802 is connected with the difference calculation unit 1803 through a conducting wire, the output end of the difference calculation unit 1803 is connected with the data output unit 1804 through a conducting wire, the data operation unit 1801, the data comparison unit 1802, the difference calculation unit 1803 and the data output unit 1804 are all electrically connected in series through conducting wires, the data comparison unit 1802 and the external big data unit 19 are electrically connected in parallel through conducting wires, when the device monitors and manages carbon emission, the data can be transmitted to the receiving box 10 according to the data monitored by the device, the data is transmitted to the data benchmarking module 18 through the data collecting unit 17 for benchmarking calculation, the data is centrally calculated through the data calculating unit 1801, the data is transmitted to the data comparing unit 1802 after calculation, meanwhile, the external big data unit 19 can transmit the standard value data of carbon emission in the database to the data comparing unit 1802 for automatic benchmarking, the data after automatic benchmarking is transmitted to the difference value calculating unit 1803, the data obtained by calculation is transmitted to the data output unit 1804 after the difference value of the two data is calculated, the data is transmitted to the data storage unit 20 through the data output unit 1804 for individual storage, when the user needs to call out the data for reading, the data can be transmitted from the data storage unit 20 through the data transmission unit 21, reading is performed, the output end of the data targeting module 18 is connected with a data storage unit 20 through a conducting wire, and the output end of the data storage unit 20 is connected with a data transmission unit 21 through a conducting wire.

The working principle of the carbon emission monitoring and managing device with the automatic benchmarking function is as follows: firstly, the insertion block 6 is inserted into the sealing groove 5 by pressing the insertion block 6, and the elastic forces at the two sides interact with each other under the elastic action of the spring 7, so that the limited fixation of the door frame 8 can be ensured, and secondly, the door frame can be pushed to one side during disassembly; secondly, when the monitoring and management equipment in the cabinet body 4 needs to be maintained, the movable door 11 can be pulled and opened under the action of the hinge 12, so that the monitoring and management equipment in the cabinet body 4 can be locally maintained; then the temperature sensor 14 and the humidity sensor 15 respectively monitor the temperature and the humidity inside the cabinet 4, the monitored data can be transmitted to the inside of the monitoring table 16 in real time, finally, the heat dissipation fan 9, the temperature sensor 14 and the humidity sensor 15 are electrically connected, when the internal temperature or the humidity rises, the heat dissipation fan 9 automatically starts to dissipate heat and dehumidify the inside of the cabinet 4, through the arrangement of the receiving box 10, the data collecting unit 17, the data operation unit 1801, the data comparison unit 1802, the difference value calculation unit 1803, the data output unit 1804, the external big data unit 19, the data storage unit 20 and the data transmission unit 21, when the device monitors and manages carbon emission, the data can be transmitted to the receiving box 10 according to the data obtained by monitoring of the device, the data is transmitted to the data benchmarking module 18 through the data collecting unit 17 to perform benchmarking calculation, through the data arithmetic unit 1801, the data are centrally calculated, after the calculation, the data are transmitted to the data comparison unit 1802, meanwhile, the external big data unit 19 can transmit the standard value data of carbon emission in the database to the data comparison unit 1802 for automatic benchmarking, the data after automatic benchmarking are transmitted to the difference value calculation unit 1803, after the difference value of the two data is calculated, the calculated data are transmitted to the data output unit 1804, the data are transmitted to the data storage unit 20 through the data output unit 1804 to be separately stored, when a user needs to call the data to read, the data can be transmitted from the data storage unit 20 through the data transmission unit 21 to be read.

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 (6)

1. The utility model provides a carbon emission control management device with automatic benchmarking function, includes base (1) and inserted block (6), its characterized in that: the lower end of the base (1) is fixedly connected with support legs (2), the interior of the base (1) is provided with a drainage groove (3), the cabinet body (4) is fixedly connected above the base (1), the interior of the cabinet body (4) is provided with a sealing groove (5), the right side of the insert block (6) is fixedly connected with a spring (7), the insert block (6) is positioned in the sealing groove (5), the right side of the spring (7) is fixedly connected with a door frame (8), the upper end of the interior of the door frame (8) is fixedly connected with a receiving box (10), a heat dissipation fan (9) is arranged below the insert block (6), the lower part of the receiving box (10) is movably connected with a movable door (11), the left side of the movable door (11) is movably connected with a hinge (12), the upper part of the cabinet body (4) is fixedly connected with a rain cover (13), the rear side of the receiving box (10) is movably connected with a humidity sensor (15), and the right side of humidity transducer (15) is provided with temperature sensor (14), the front end swing joint of receiving box (10) has monitoring table (16), and the output of receiving box (10) is connected with data collection unit (17) through the wire, the output of data collection unit (17) is connected with data pair mark module (18) through the wire, and the input of data pair mark module (18) is connected with outside big data unit (19) through the wire, the output of data pair mark module (18) is connected with data storage unit (20) through the wire, and the output of data storage unit (20) is connected with data transmission unit (21) through the wire.

2. The carbon emission monitoring and management device with the automatic benchmarking function according to claim 1, characterized in that: the upper surface of base (1) and the lower surface of the cabinet body (4) are closely attached, and the support legs (2) are symmetrical about the central axis of the cabinet body (4).

3. The carbon emission monitoring and management device with the automatic benchmarking function according to claim 1, characterized in that: the sealing grooves (5) are symmetrical relative to the central axis of the cabinet body (4), and the inner size of the sealing grooves (5) is matched with the outer size of the inserting blocks (6).

4. The carbon emission monitoring and management device with the automatic benchmarking function according to claim 1, characterized in that: the insert block (6) forms an elastic structure with the door frame (8) through the spring (7), and the springs (7) are symmetrical relative to the central axis of the door frame (8).

5. The carbon emission monitoring and management device with the automatic benchmarking function according to claim 1, characterized in that: the data benchmarking module (18) comprises a data operation unit (1801), a data comparison unit (1802), a difference value calculation unit (1803) and a data output unit (1804), wherein the output end of the data operation unit (1801) is connected with the data comparison unit (1802) through a conducting wire, the output end of the data comparison unit (1802) is connected with the difference value calculation unit (1803) through a conducting wire, and the output end of the difference value calculation unit (1803) is connected with the data output unit (1804) through a conducting wire.

6. The carbon emission monitoring and management device with the automatic benchmarking function according to claim 5, characterized in that: the data operation unit (1801), the data comparison unit (1802), the difference calculation unit (1803) and the data output unit (1804) are electrically connected in series through a conducting wire, and the data comparison unit (1802) and the external big data unit (19) are electrically connected in parallel through a conducting wire.

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