CN114387702B - Monitoring method for carbon emission process - Google Patents

Abstract

The invention provides a method for monitoring a carbon emission process, which can realize the monitoring of the carbon emission process and alarm when the carbon emission threshold exceeds a preset carbon emission threshold by an alarm device. The supervision method comprises the following steps: determining index parameters related to the monitored target carbon emission; setting upper and lower limit values of index parameters according to the total carbon emission amount requirement in a certain period; carrying out multiple measurements on the index parameter within a preset period to obtain multiple measurement values; calculating the standard deviation of the measured values; calculating a control coefficient; and comparing the control coefficient with a preset threshold value, and alarming through an alarm device when the control coefficient exceeds the preset threshold value.

Description

Monitoring method for carbon emission process

Technical Field

The invention relates to the field of monitoring of carbon emission processes.

Background

At present, most of existing carbon emission monitoring methods directly measure carbon emission based on primary energy consumption or total energy consumption, calculate the actual carbon emission in a target unit within a certain time, use fixed parameters for carbon emission coefficients of different periods, different areas or industries, and not consider the reduction of the carbon emission coefficient of the energy consumption and the difference of the carbon emission coefficients between the areas and the industries caused by technical progress, but only measure the current carbon emission result of the target unit, and the result accumulation only reflects the change trend and phenomenon of the carbon emission, so that the controllability and the adjustability of the carbon emission process under the premise of limiting the total quantity are lost. Therefore, further improvement in carbon emission measurement is needed to obtain more accurate data.

Disclosure of Invention

The invention aims to: in order to overcome the defects in the prior art, the invention provides a method for monitoring a carbon emission process to solve the problems of uncontrollable and inaccurate measurement of the carbon emission process in the prior art.

The technical scheme is as follows: in order to achieve the above purpose, the technical scheme of the invention is as follows:

the monitoring method of the carbon emission process comprises the following steps:

a first step of: determining index parameters related to the monitored target carbon emission;

and a second step of: setting upper and lower limit values of index parameters according to the total carbon emission amount requirement in a certain period;

and a third step of: carrying out multiple measurements on the index parameter within a preset period to obtain multiple measurement values;

fourth step: calculating the standard deviation of the measured values;

fifth step: calculating a control coefficient;

sixth step: and comparing the control coefficient with a preset threshold value, and alarming through an alarm device when the control coefficient exceeds the preset threshold value.

Further, the measuring device is used for measuring the electricity consumption of the monitoring target so as to generate and output a corresponding measuring result; setting N measurement time points in the preset period, and measuring the index parameters of the monitoring target by the measurement device when the N measurement time points are set, so as to obtain measurement results Xi corresponding to the N measurement time points, wherein N is a positive integer greater than 1, 0<i is less than or equal to N, and i represents a plurality of measurement time points.

Further, calculating and obtaining a mean value of the plurality of measurement results according to the plurality of measurement results; according to the average value of the measurement results, calculating and obtaining a standard deviation corresponding to the average value, wherein the calculation formula is as follows:

further, the control coefficient is calculated according to the formula s= (H-L)/6 e.

Further, the alarm adopts an alarm device to alarm; the alarm device is fixedly arranged on one side of the measuring device and is electrically connected with a control system in the measuring device; the alarm device comprises a mounting block and an alarm; the mounting block is fixed on the measuring device; the top of the mounting block is wedge-shaped; a fan-shaped groove is formed in the middle of the top of the mounting block; a swinging structure is arranged in the fan-shaped groove; an alarm is arranged on the swinging end of the swinging structure; the swinging end of the swinging structure drives the alarm to enter and exit the fan-shaped groove, and the swinging end of the swinging structure drives the alarm to swing reciprocally along the arc track of the fan-shaped groove.

Further, the swing structure includes a movement axis; the fan-shaped groove bottom driving device is in driving connection with one end of the motion shaft; an alarm is fixedly arranged at the other end of the motion shaft; a shielding structure is arranged at the notch of the fan-shaped groove; the shielding structure comprises a cover plate; the cover plates are symmetrically arranged in a side-by-side splicing way, and one side edge of each cover plate is connected with the inner wall of the notch of the fan-shaped groove through an elastic reset key; the cover plate is of a transparent material structure and correspondingly covers the fan-shaped groove; the movement shaft drives the alarm to prop up and open the symmetrically-spliced cover plates to be away from each other, and the movement shaft drives the alarm to extend out of the fan-shaped groove and swing.

Furthermore, the two sides of one end of the movement shaft, provided with the alarm, are symmetrically and fixedly provided with matching plates; the symmetrical matching plates are arranged along the width direction of the fan-shaped groove; the middle part of one side of the matching plate far away from the motion shaft is provided with a containing groove; the notch of the accommodating groove is gradually reduced; a plurality of balls are filled in the accommodating groove; the balls are arranged side by side along the axis direction of the motion shaft; the ball part protrudes out of the accommodating groove; when the movement shaft drives the alarm to swing, the balls correspondingly roll back and forth on the side wall of the cover plate.

The beneficial effects are that: according to the technical scheme, the index parameters related to the carbon emission process of the monitoring target and the upper limit value and the lower limit value of the corresponding index parameters are determined, the index parameters of the monitoring target are measured in a preset period to obtain a corresponding measurement result, the standard deviation is calculated according to the measurement result, the control coefficient is calculated, the control coefficient is compared with a preset threshold value, and an alarm is given when the preset threshold value is exceeded. Therefore, a user can know and master whether the abnormal state exists in the whole monitoring control process in real time according to the existence of the alarm, and does not need to pay attention to specific carbon emission results, so that the situation that the result calculated according to the measured actual carbon emission is uncontrollable and inaccurate and is wrong in judgment is avoided, and the convenience in use is improved; and the alarm is when reporting to the police, and the oscillating structure drives the alarm and stretches out the fan-shaped groove to reciprocal swing, on the one hand can remind personnel to pay attention to through the alarm sound of alarm and the alarm lamp of scintillation, on the other hand can be through the reciprocating motion of alarm come more showing the attention of reminding personnel.

Drawings

FIG. 1 is a step diagram of a supervision method;

FIG. 2 is a diagram of the alarm device;

FIG. 3 is a diagram of a swing structure;

fig. 4 is a structural view of the mating board.

Detailed Description

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

As shown in fig. 1-4: the monitoring method of the carbon emission process comprises the following steps:

a first step of: determining index parameters related to the monitored target carbon emission;

and a second step of: setting upper and lower limit values of index parameters according to the total carbon emission amount requirement in a certain period;

and a third step of: carrying out multiple measurements on the index parameter within a preset period to obtain multiple measurement values;

fourth step: calculating the standard deviation of the measured values;

fifth step: calculating a control coefficient;

sixth step: and comparing the control coefficient with a preset threshold value, and alarming through an alarm device when the control coefficient exceeds the preset threshold value.

Measuring the electricity consumption of the monitoring target through the measuring device so as to generate and output a corresponding measuring result; setting N measurement time points in the preset period, and measuring the index parameters of the monitoring target by the measurement device when the N measurement time points are set, so as to obtain measurement results Xi corresponding to the N measurement time points, wherein N is a positive integer greater than 1, 0<i is less than or equal to N, and i represents a plurality of measurement time points.

And, the measurement time point may be in units of hours, days or months, for example, and the measurement time point may be continuous or discontinuous. For example, assuming that N is set to 3, when the measurement time points are in units of hours and are continuous, the measurement apparatus generates one measurement result at, for example, 1 point, then one measurement result at 2 points, and then one measurement result at 3 points. When the measurement time points are in hours and discontinuous, the measurement device generates a measurement result at, for example, 1 point, then generates a measurement result at 3 points, and then generates a measurement result at 7 points.

Calculating and obtaining a mean value of the plurality of measurement results according to the plurality of measurement results; according to the average value of the measurement results, calculating and obtaining a standard deviation corresponding to the average value, wherein the calculation formula is as follows:

wherein e is the standard deviation, xi is the plurality of measurement results, X is the average value of the plurality of measurement results, and N is the number of measurement time points.

Calculating the control coefficient according to the formula s= (H-L)/6 e; wherein S is the control coefficient, H is the upper limit value, L is the lower limit value, and e is the standard deviation. That is, the control coefficient S can be calculated by substituting the obtained upper limit value H, lower limit value L, and calculated standard deviation e into the above formula.

Alarming when the control coefficient exceeds a preset threshold value; the preset threshold value can be adjusted and set by the user according to the requirement, and the alarm can be sound, text, etc., and is generated by an alarm device, such as a speaker, a loudspeaker, a display, etc. Therefore, a user can know and master whether the abnormal state exists in the whole monitoring control process in real time according to the existence of the alarm, and the specific carbon emission results do not need to be paid attention to any more, so that the uncontrollable and inaccurate results calculated according to the actual carbon emission measurement are avoided, and the judgment error is caused, thereby improving the use convenience.

The alarm adopts an alarm device 1 to alarm; the alarm device 1 is fixedly arranged on one side of the measuring device, and the alarm device 1 is electrically connected with a control system in the measuring device; the alarm device 1 comprises a mounting block 11 and an alarm 12; the mounting block 11 is fixed on a measuring device; the top of the mounting block 11 is wedge-shaped; a fan-shaped groove 111 is formed in the middle of the top of the mounting block 11; a swinging structure 2 is arranged in the fan-shaped groove 111; an alarm 12 is arranged on the swinging end of the swinging structure 2; the swinging end of the swinging structure 2 drives the alarm 12 to enter and exit the fan-shaped groove 111, and the swinging end of the swinging structure 2 drives the alarm 12 to swing reciprocally along the arc-shaped track of the fan-shaped groove 111. When the control coefficient exceeds a preset threshold, the measuring device outputs a signal to the alarm device, the alarm correspondingly gives an alarm, and the alarm sound and the alarm lamp flash; meanwhile, the swinging structure drives the alarm to reciprocate so as to more obviously prompt the attention of personnel.

The oscillating structure 2 comprises a movement axis 21; the driving device at the bottom of the fan-shaped groove 111 is in driving connection with one end of the moving shaft 21; an alarm 12 is fixedly arranged at the other end of the movement shaft 21; a shielding structure 13 is arranged at the notch of the fan-shaped groove 111; the shielding structure 13 comprises a cover sheet 131; the cover plates 131 are symmetrically arranged in a side-by-side splicing way, and one side edge of each cover plate 131 is connected with the inner wall of the notch of the fan-shaped groove 111 through an elastic reset key; the cover plate 131 is made of transparent material and correspondingly covers the fan-shaped groove 111; the moving shaft 21 drives the alarm 12 to push the symmetrically-spliced cover plates 131 away from each other, and the moving shaft 21 drives the alarm 12 to extend out of the fan-shaped groove 111 and swing. When the movement shaft drives the alarm to be retracted into the fan-shaped groove, the elastic reset key drives the cover plate to be spliced to cover the fan-shaped groove, so that the alarm is protected, meanwhile, the cover plate is of a transparent structure, and when an alarm starts, a person can hear the alarm sound and can see the alarm through the cover plate; when the movement shaft drives the alarm to extend out of the fan-shaped groove and drives the alarm to swing back and forth, people can pay attention more obviously, and the alarm effect is improved.

The two sides of one end of the movement shaft 21, where the alarm 12 is arranged, are symmetrically and fixedly provided with matching plates 22; the symmetrical matching plates 22 are arranged along the width direction of the fan-shaped groove 111; the middle part of one side of the matching plate 22 away from the motion shaft 21 is provided with a containing groove 221; the notch of the accommodating groove 221 gradually decreases; a plurality of balls 222 are filled in the accommodating groove 221; the balls 222 are arranged side by side along the axial direction of the moving shaft 21; the ball 222 protrudes from the accommodating groove 221; when the movement shaft 21 drives the alarm 12 to swing, the balls 222 correspondingly roll back and forth on the side wall of the cover plate 131. When the alarm extends out of the fan-shaped groove, the matching plate correspondingly matches and pushes the cover plate, and the ball slides on the cover plate, so that the convenience of pushing and withdrawing is facilitated; meanwhile, when the alarm swings, the balls correspondingly roll back and forth on the cover plate, abrasion is reduced through rolling, the alarm can be protected, and the alarm is prevented from being damaged.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the invention, but it is intended to cover any modifications, equivalents, and improvements within the scope of the present invention by those skilled in the art without departing from the principles of the present invention.

Claims (6)

1. The monitoring method of the carbon emission process comprises the following steps:

a first step of: determining index parameters related to the monitored target carbon emission;

and a second step of: setting upper and lower limit values of index parameters according to the total carbon emission amount requirement in a certain period;

and a third step of: carrying out multiple measurements on the index parameter within a preset period to obtain multiple measurement values;

fourth step: calculating the standard deviation of the measured values;

fifth step: calculating a control coefficient;

sixth step: comparing the control coefficient with a preset threshold, and alarming through an alarm device when the control coefficient exceeds the preset threshold;

the alarm adopts an alarm device (1) to alarm; the alarm device (1) is fixedly arranged on one side of the measuring device, and the alarm device (1) is electrically connected with a control system in the measuring device; the alarm device (1) comprises a mounting block (11) and an alarm (12); the mounting block (11) is fixed on the measuring device; the top of the mounting block (11) is wedge-shaped; a fan-shaped groove (111) is formed in the middle of the top of the mounting block (11); a swinging structure (2) is arranged in the fan-shaped groove (111); an alarm (12) is arranged at the swinging end of the swinging structure (2); the swinging end of the swinging structure (2) drives the alarm (12) to enter and exit the fan-shaped groove (111), and the swinging end of the swinging structure (2) drives the alarm (12) to swing reciprocally along the arc-shaped track of the fan-shaped groove (111);

the oscillating structure (2) comprises a movement axis (21); the groove bottom driving device of the fan-shaped groove (111) is in driving connection with one end of the moving shaft (21); an alarm (12) is fixedly arranged at the other end of the movement shaft (21); a shielding structure (13) is arranged at the notch of the fan-shaped groove (111); the shielding structure (13) comprises a cover sheet (131); the cover plates (131) are symmetrically arranged in a side-by-side spliced mode, and one side edge of each cover plate (131) is connected with the inner wall of a notch of the fan-shaped groove (111) through an elastic reset key; the cover plate (131) is of a transparent material structure and correspondingly covers the fan-shaped groove (111); the movement shaft (21) drives the alarm (12) to jack up the symmetrically spliced cover plates (131) to be far away from each other, and the movement shaft (21) drives the alarm (12) to extend out of the fan-shaped groove (111) and swing;

the two sides of one end of the movement shaft (21) provided with the alarm (12) are symmetrically and fixedly provided with matching plates (22); the symmetrical matching plates (22) are arranged along the width direction of the fan-shaped groove (111); the middle part of one side of the matching plate (22) far away from the motion shaft (21) is provided with a containing groove (221); the notch of the accommodating groove (221) is gradually reduced; a plurality of balls (222) are filled in the accommodating groove (221); the balls (222) are arranged side by side along the axial direction of the moving shaft (21); the ball (222) partially protrudes out of the accommodating groove (221); when the movement shaft (21) drives the alarm (12) to swing, the balls (222) correspondingly roll back and forth on the side wall of the cover plate (131).

2. A method for monitoring a carbon emission process according to claim 1, wherein: the index parameters comprise electricity consumption; the monitoring target is a unit, home or community having a product that generates electricity or a product that generates electricity.

3. A method for monitoring a carbon emission process according to claim 2, wherein: the upper limit value and the lower limit value are set according to the total carbon emission requirement in a certain period; the certain period is one month, two months, half year or one year.

4. A method of monitoring a carbon emissions process according to claim 3, wherein: measuring the electricity consumption of the monitoring target through the measuring device so as to generate and output a corresponding measuring result; setting N measurement time points in the preset period, and measuring the index parameters of the monitoring target by the measurement device when the N measurement time points are set, so as to obtain measurement results Xi corresponding to the N measurement time points, wherein N is a positive integer greater than 1, 0<i is less than or equal to N, and i represents a plurality of measurement time points.

5. The method for monitoring a carbon emission process according to claim 4, wherein: calculating and obtaining a mean value of the plurality of measurement results according to the plurality of measurement results; according to the average value of the measurement results, calculating and obtaining a standard deviation corresponding to the average value, wherein the calculation formula is as follows:

6. the method for monitoring a carbon emission process according to claim 5, wherein: the control coefficient is calculated according to the formula s= (H-L)/6 e.