CN117575139A - Carbon emission monitoring system in building process - Google Patents

Abstract

The invention relates to a carbon emission monitoring system in a building process, which mainly relates to the technical field of carbon emission monitoring, and comprises an information acquisition module, a prediction module, a transportation analysis module, an adjustment module, a decoration analysis module, a correction module, a waste treatment module, a waste analysis module, a monitoring module, an early warning module and an optimization module, wherein the information acquisition module is used for acquiring building information, transportation information, energy consumption information, environment information and paint information, the prediction module is used for analyzing preset carbon emission in each stage, the transportation analysis module is used for analyzing the carbon emission in a material transportation stage, the adjustment module is used for adjusting the analysis process of the carbon emission in the material transportation stage, the decoration analysis module is used for analyzing the carbon emission in the decoration stage, the correction module is used for correcting the preset carbon emission in the waste treatment stage, the waste analysis module is used for analyzing the carbon emission in the waste treatment stage, the monitoring module is used for early warning according to the analysis result of the carbon emission in each stage, and the analysis process of the preset carbon emission is optimized.

Description

Carbon emission monitoring system in building process

Technical Field

The invention relates to the technical field of carbon emission monitoring, in particular to a carbon emission monitoring system in a building process.

Background

Carbon emission monitoring is of critical importance for coping with climate change, protecting the environment, promoting sustainable development and achieving global climate goals. By collecting, analyzing, and utilizing emissions data, one can better understand and address climate challenges.

The carbon emission monitoring system analyzes the preset carbon emission of each stage according to the building area, analyzes the carbon emission of each stage, adjusts the preset carbon emission of the next stage according to the analysis result, pre-warns abnormal carbon emission, optimizes the analysis process of the preset carbon emission according to the total carbon emission, and improves the monitoring efficiency of the carbon emission.

Chinese patent publication No.: CN116340850B discloses a method and a system for monitoring carbon emission in a building process, which relate to the technical field of carbon emission monitoring, and the method comprises the following steps: collecting an energy operation data set of a first building project, wherein the energy operation data set is stored in a partition block; acquiring an energy conversion rate set, wherein the number of the energy conversion rate set corresponds to the number of the blocks; clustering the energy conversion rate set to obtain a clustering result; merging the block sets according to the clustering result, and outputting a carbon-row distributed block chain; building a plurality of carbon row monitoring channels; performing carbon row monitoring result fitting according to the plurality of carbon row monitoring channels, and generating first early warning information according to fitting results; it can be seen that the solution does not analyze the building process when monitoring the carbon emissions, and has the problem of low efficiency of monitoring the carbon emissions in the building process.

Disclosure of Invention

Therefore, the invention provides a carbon emission monitoring system in the building process, which is used for solving the problem of low carbon emission monitoring efficiency in the building process in the prior art.

To achieve the above object, the present invention provides a carbon emission monitoring system in a construction process, the system comprising,

the information acquisition module is used for acquiring building information, transportation information, energy consumption information, environment information and paint information;

the pre-estimating module is used for analyzing the preset carbon emission of the material transportation stage, the decoration stage and the waste treatment stage according to the acquired building area;

the transport analysis module is used for analyzing the carbon emission of the material transport stage according to the type of the obtained material transport vehicle and the material transport distance, and adjusting the preset carbon emission of the decoration stage according to the analysis result;

the adjusting module is used for adjusting the analysis process of the carbon emission in the material transportation stage according to the acquired transportation time and the acquired environmental humidity;

the decoration analysis module is used for analyzing the carbon emission in the decoration stage according to the adjustment result of the transportation analysis module on the preset carbon emission in the decoration stage, the acquired electric energy consumption, the content of VOCs in the paint and the quality of the paint, and adjusting the preset carbon emission in the waste treatment stage according to the analysis result;

The correction module is used for correcting the adjustment process of the preset carbon emission in the waste treatment stage according to the acquired ambient temperature and precipitation;

the waste analysis module is used for analyzing the carbon emission of the waste treatment stage according to the adjustment result of the decoration analysis module on the preset carbon emission of the waste treatment stage, the type of the obtained waste transport vehicle and the waste transport distance;

the monitoring module is used for carrying out early warning according to the analysis result of the carbon emission of each stage;

and the optimizing module is used for optimizing the analysis process of the preset carbon emission according to the analysis result of the carbon emission of each stage.

Further, the prediction module compares the obtained building area s0 with a preset area s1, and analyzes preset carbon emission of each stage according to the comparison result, wherein:

when s0 is less than s1, the pre-estimating module sets the preset carbon emission of the material transportation stage as A1, the preset carbon emission of the decoration stage as B1 and the preset carbon emission of the waste treatment stage as C1;

when s0 is greater than or equal to s1, the pre-estimation module sets the preset carbon emission of the material transportation stage as A2, sets a2=a0×a1, sets the preset carbon emission of the decoration stage as B2, sets b2=a0×b1, sets the preset carbon emission of the waste treatment stage as C2, and sets c2=a0×c1.

Further, the transport analysis module determines a carbon emission factor according to the acquired material transport vehicle type pair, and analyzes carbon emissions in a material transport stage according to an analysis result of the transport distance and the carbon emission factor, wherein:

when the material transporting vehicle type is a small-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle as b1, and sets the carbon emission of the vehicle as e1, and sets e1=l1×b1/v;

when the material transporting vehicle type is a medium-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e2, and sets e2=l2×b2/v;

when the material transporting vehicle type is a large-sized vehicle, the transportation analysis module sets the carbon emission factor of the vehicle as b3, and sets the carbon emission of the vehicle as e3, and sets e3=l3×b3/v;

the transportation analysis module sets the carbon emission of the material in the transportation stage as E1, and sets E1=e1+e2+e3, and if E1 is less than or equal to Aa, the transportation analysis module judges that the carbon emission is normal and does not adjust; if E1 > Aa, the transport analysis module determines that the carbon emission is abnormal and adjusts the preset carbon emission in the decoration stage, and the transport analysis module sets the adjusted preset carbon emission in the decoration stage as Bb ', and sets Bb' =bb- (E1-Aa).

Further, the adjustment module is provided with an adjustment unit, the adjustment unit calculates an average speed V0 according to the acquired transportation time t and the material transportation path, compares a calculation result with a preset speed, and adjusts carbon emission E1 of the material transportation stage according to the comparison result, wherein:

when V0 is less than or equal to V1, the regulating unit judges that the average speed is small, and sets a regulating coefficient alpha 1 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 1 = 1- (V1-V0)/(V1 + V0);

when V1 is smaller than V0 and smaller than V2, the regulating unit judges that the average speed is normal and does not regulate;

when V0 is more than or equal to V2, the regulating unit judges that the average speed is high, and sets a regulating coefficient alpha 2 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 2 = 1+ (V0-V2)/(V2 + V0);

the adjusting unit adjusts the carbon emission E1 of the material transportation stage according to the adjusting coefficient αd, and sets the adjusted carbon emission E1 of the material transportation stage as E1', and sets E1' =e1×αd, d=1, 2;

the adjustment module is also provided with a correction unit, the correction unit compares the acquired ambient humidity u0 with preset humidity u1 and corrects the adjustment process of the carbon emission E1 in the material transportation stage according to the comparison result, wherein:

When u0 is less than or equal to u1, the correction unit judges that the humidity is normal and does not correct;

when u0 > u1, the correction means determines that the humidity is abnormal, sets a correction coefficient β to correct the adjustment coefficient αd, sets β=1+ (u 0-u 1)/(u0+u1), sets the corrected adjustment coefficient αd to αd ', and sets αd' =αd×β.

Further, the decoration analysis module is provided with an electric carbon emission analysis unit which analyzes carbon emission of electric power according to the electric energy consumption r1, the electric carbon emission analysis unit sets electric carbon emission as D1, d1=r1×b4, b4 is an electric carbon emission factor, the decoration analysis module is provided with a paint carbon emission analysis unit which analyzes carbon emission of paint according to the obtained content U of VOCs in paint and the paint mass m, and the paint carbon emission analysis unit sets paint carbon emission as D2, d2=u×m.

Further, the decoration analysis module is provided with a decoration carbon emission analysis unit which analyzes carbon emission in a decoration stage according to an analysis result of electric power carbon emission and paint carbon emission, and the decoration carbon emission analysis unit sets the carbon emission in a second stage as E2, sets e2=d1+d2, wherein:

When E1 is less than or equal to Aa, if E2 is less than or equal to Bb, the decoration carbon emission analysis unit judges that the carbon emission is normal, and no adjustment is performed; if E2 > Bb, the decoration carbon emission analysis unit determines that the carbon emission is abnormal, and adjusts the preset carbon emission of the waste treatment stage, and the decoration carbon emission analysis unit sets the preset carbon emission of the adjusted waste treatment stage as Cc ', and sets Cc' =cc- (E2-Bb);

when E1 > Aa, if E2 is less than or equal to Bb', the decoration carbon emission analysis unit judges that the carbon emission is normal; if E2 > Bb ', the finishing carbon emission analysis unit determines that the carbon emission is abnormal and adjusts the preset carbon emission in the waste treatment stage, and the finishing carbon emission analysis unit sets the adjusted preset carbon emission in the waste treatment stage as Cc', and sets Cc '=cc- (E2-Bb').

Further, the correction module is provided with a correction unit, the correction unit compares the acquired ambient temperature t0 with each preset temperature, and corrects the adjustment process of the preset carbon emission of the waste treatment stage according to the comparison result, wherein:

when t0 < t1, the correction unit determines that the ambient temperature is low, and sets a correction coefficient H1 to correct the preset carbon emission Cc' of the waste treatment stage, and sets h1=1+ (t 1-t 0)/(t1+t0);

When t1 is less than or equal to t0 and less than or equal to t2, the correction unit judges that the ambient temperature is normal and does not correct;

when t0 is more than or equal to t2, the correction unit judges that the ambient temperature is high, sets a correction coefficient H2 to correct the preset carbon emission Cc' of the waste treatment stage, and sets H2+ (t 0-t 2)/(t2+t0);

the correction unit corrects the preset carbon emission Cc ' of the waste treatment stage according to the correction coefficient Hh, and sets the corrected preset carbon emission Cc ' of the waste treatment stage as Cc ", sets Cc" =cc ' ×hh, and sets h=1, 2;

the correction module is also provided with a compensation unit, the compensation unit compares the acquired precipitation p0 during decoration with a preset precipitation p1 and compensates the correction process of the adjustment process of the preset carbon emission of the waste treatment stage according to the comparison result, wherein:

when p0 is less than p1, the compensation unit judges that the precipitation is normal and does not compensate;

when p0 is greater than or equal to p1, the compensation unit determines that the precipitation is abnormal, sets a compensation coefficient as k, sets k=1- (p 0-p 1)/(p0+p1), compensates the correction coefficient H2 according to the compensation coefficient k, sets the compensated correction coefficient H2 as H2', and sets H2' =h2×k.

Further, the waste analysis module determines a carbon emission factor according to the acquired type of the waste transport vehicle, and analyzes carbon emissions during a material transport phase according to an analysis result of the transport distance and the carbon emission factor, wherein:

When the type of the waste transport vehicle is a small car, the waste analysis module sets the carbon emission factor of the vehicle to b1, and the carbon emission of the vehicle to e4, and sets e4=l4×b1/v;

when the type of the waste transport vehicle is a medium-sized vehicle, the waste analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e5, setting e5=l5×b2/v;

when the type of the scrap transporting vehicle is a large-sized vehicle, the scrap analyzing module sets the carbon emission factor of the vehicle to b3 and the carbon emission of the vehicle to e6, and sets e6=l6×b3/v.

Further, the monitoring module compares the analysis result of the carbon emission of each stage with the preset carbon emission of each stage, and performs early warning according to the comparison result, wherein:

when E1 is less than or equal to Aa in the material transportation stage, the monitoring module judges that the carbon emission is normal in the material transportation stage, early warning is not carried out, and when E1 is more than Aa, the monitoring module judges that the carbon emission is excessive in the material transportation stage, and early warning is carried out;

when E1 is less than or equal to Aa and less than or equal to Bb in the decoration stage, the monitoring module judges that the carbon emission is normal in the decoration stage, early warning is not carried out, and when E2 is more than Bb, the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out; when E1 is more than Aa, if E2 is less than or equal to Bb ', the monitoring module judges that the carbon emission is normal in the decoration stage, no early warning is carried out, and if E2 is more than Bb', the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out;

In the waste treatment stage, when E2 is less than or equal to Bb or E2 is less than or equal to Bb', if E3 is less than or equal to Cc, the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is more than Cc, the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out; when E2 is larger than Bb or E2 is larger than Bb ', if E3 is smaller than or equal to Cc ', the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is larger than Cc ', the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out.

Further, the optimization module sums the carbon emissions of the stages to obtain a total carbon emission E _{Real world} And with the sum E of the respective preset carbon emissions _{Pre-preparation} Comparing, and optimizing an analysis process of the preset carbon emission of each building stage according to the comparison result, wherein:

when E is _{Real world} ≤E _{Pre-preparation} When the total carbon emission is normal, the optimization module judges that the total carbon emission is not optimized;

when E is _{Real world} ＞E _{Pre-preparation} If (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} J is less than or equal to, the optimization module judges that the total carbon emission is normal, and optimization is not performed; if (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} The optimizing module judges that the total carbon emission is abnormal and sets an optimizing coefficient gamma to optimize the preset carbon emission of each building stage of each stage, and sets gamma=1+ (E _{Real world} -E _{Pre-preparation} )/(E _{Real world} +E _{Pre-preparation} ) The method includes setting a preset carbon emission Aa of an optimized material transportation stage to Aa1, setting aa1=aa×γ, setting a preset carbon emission Bb of an optimized finishing stage to Bb1, setting bb1=bb×γ, setting a preset carbon emission Cc of an optimized waste material treatment stage to Cc1, and setting cc1=cc×γ.

Compared with the prior art, the method has the advantages that the pre-estimation module improves the accuracy of the pre-set carbon emission analysis of each stage by setting the pre-set area so as to improve the accuracy of the actual carbon emission analysis of each stage, thereby improving the monitoring efficiency of the carbon emission in the building process, the transportation analysis module improves the accuracy of the carbon emission analysis of the material transportation stage by acquiring different vehicle types, further improves the accuracy of the pre-set carbon emission analysis of the decoration stage, thereby improving the monitoring efficiency of the carbon emission in the building process, the adjusting unit improves the accuracy of the adjusting coefficient by setting the pre-set speed, thereby reducing the influence of the transportation speed on the carbon emission of the vehicle, further improving the accuracy of the pre-set carbon emission analysis of the decoration stage, thereby improving the monitoring efficiency of the carbon emission in the building process, and the correcting unit improves the monitoring efficiency of the carbon emission in the building process by setting the pre-set humidity The accuracy of the high correction coefficient is improved, thereby reduce the influence of environmental humidity on the carbon emission of the vehicle, and then improve the accuracy of the analysis of the preset carbon emission in the finishing stage, and thereby improve the monitoring efficiency of the carbon emission in the building process, the compensation unit sums the electric carbon emission with the paint carbon emission by setting the preset precipitation amount, and compares with the preset carbon emission in the preset finishing stage, and then improves the accuracy of the analysis of the preset carbon emission in the waste treatment stage, and thereby improves the monitoring efficiency of the carbon emission in the building process, and the accuracy of the correction coefficient is improved by setting the preset temperature, thereby reduces the influence of the environmental temperature on the carbon emission in the finishing stage, and then improves the accuracy of the analysis of the preset carbon emission in the waste treatment stage, and thereby improves the monitoring efficiency of the carbon emission in the building process by setting the carbon emission in the early warning stage according to the prior art, and the monitoring efficiency of the carbon emission in the building process is improved by setting the carbon emission in the early warning stage by setting the preset precipitation amount, and then improves the monitoring efficiency of the carbon emission in the building process by using the early warning module _{Pre-preparation} The accuracy of the optimization coefficient is improved, and the accuracy of the analysis of the preset carbon emission in each stage is further improved, so that the monitoring efficiency of the carbon emission in the building process is improved, and the monitoring efficiency of the carbon emission in the building process is improved.

Drawings

FIG. 1 is a schematic diagram of a carbon emission monitoring system in the construction process of the present embodiment;

FIG. 2 is a schematic diagram of the adjusting module according to the present embodiment;

FIG. 3 is a schematic diagram of a decoration analysis module according to the present embodiment;

fig. 4 is a schematic structural diagram of the calibration module according to the present embodiment.

Description of the embodiments

In order that the objects and advantages of the invention will become more apparent, the invention will be further described with reference to the following examples; it should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are merely for explaining the technical principles of the present invention, and are not intended to limit the scope of the present invention.

It should be noted that, in the description of the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to the specific circumstances.

Referring to fig. 1, a schematic diagram of a carbon emission monitoring system in the construction process according to the present embodiment is shown, the system includes,

the system comprises an information acquisition module, a control module and a control module, wherein the information acquisition module is used for acquiring building information, transportation information, energy consumption information, environment information and paint information, the building information is a building area, the transportation information comprises a material transportation vehicle type, a material transportation distance, a material transportation time, a waste transportation distance and a waste transportation vehicle type, the environment information comprises an environment temperature, an environment humidity and a precipitation amount, the energy consumption information is an electric energy consumption amount, and the paint information comprises a VOCs content and paint quality in paint; in this embodiment, the method for acquiring building information, transportation information, energy consumption information, environmental information and paint information is not specifically limited, and can be freely set by a person skilled in the art, so long as the requirements for acquiring building information, transportation information, energy consumption information, environmental information and paint information are met, wherein the building information can be acquired through interaction, the type of a material transportation vehicle and the transportation time can be acquired through interaction, the transportation distance can be acquired through map software, the energy consumption information can be acquired through an ammeter, the environmental information can be acquired through a weather website, and the paint information can be acquired through interaction;

The pre-estimating module is used for analyzing the preset carbon emission of the material transportation stage, the decoration stage and the waste treatment stage according to the acquired building area, and is connected with the information acquisition module;

the transportation analysis module is used for analyzing carbon emission in a material transportation stage according to the type of the obtained material transportation vehicle and the material transportation distance, adjusting preset carbon emission in a decoration stage according to an analysis result, and connecting with the estimation module;

the adjusting module is used for adjusting the analysis process of carbon emission in the material transportation stage according to the acquired transportation time and the acquired environmental humidity, and is connected with the transportation analysis module;

the decoration analysis module is used for analyzing the carbon emission in the decoration stage according to the adjustment result of the transportation analysis module on the preset carbon emission in the decoration stage, the acquired electric energy consumption, the VOCs content in the paint and the paint quality, adjusting the preset carbon emission in the waste treatment stage according to the analysis result, and connecting the decoration analysis module with the adjustment module;

the correction module is used for correcting the adjustment process of the preset carbon emission in the waste treatment stage according to the acquired environmental temperature and precipitation, and is connected with the decoration analysis module;

The waste analysis module is used for analyzing the carbon emission of the waste treatment stage according to the adjustment result of the decoration analysis module on the preset carbon emission of the waste treatment stage, the type of the obtained waste transport vehicle and the waste transport distance, and is connected with the correction module;

the monitoring module is used for carrying out early warning according to the analysis result of the carbon emission of each stage and is connected with the waste analysis module;

and the optimizing module is used for optimizing the analysis process of the preset carbon emission according to the analysis result of the carbon emission at each stage, and is connected with the monitoring module.

Fig. 2 is a schematic structural diagram of an adjustment module according to the present embodiment, where the adjustment module includes,

the adjusting unit is used for adjusting the analysis process of the carbon emission in the material transportation stage according to the acquired material transportation time;

the correcting unit is used for correcting the adjustment process of the analysis process of the carbon emission in the material transportation stage according to the acquired environmental humidity, and is connected with the adjustment unit;

referring to fig. 3, a schematic structural diagram of a decoration analysis module according to the present embodiment is shown, where the decoration analysis module includes,

An electric power carbon emission analysis unit for analyzing carbon emission of electric power according to the obtained electric power consumption;

the paint carbon emission analysis unit is used for analyzing carbon emission of the paint according to the content of VOCs in the obtained paint and the quality of the paint, and is connected with the electric power carbon emission analysis unit;

the decoration carbon emission analysis unit is used for analyzing carbon emission in a decoration stage according to the analysis results of electric carbon emission and paint carbon emission, and is connected with the paint carbon emission analysis unit;

referring to fig. 4, a schematic structural diagram of a calibration module according to the present embodiment is shown, where the calibration module includes,

the correction unit is used for correcting the adjustment process of the preset carbon emission in the waste treatment stage according to the acquired environmental temperature;

and the compensation unit is used for compensating the correction process of the adjustment process of the preset carbon emission of the waste treatment stage according to the acquired precipitation amount, and is connected with the correction unit.

Specifically, the carbon emission monitoring system in the building process is applied to carbon emission monitoring in the decoration process, analyzes the preset carbon emission of each stage according to the building area, adjusts the preset carbon emission of the next stage according to the analysis result, pre-warns abnormal carbon emission, optimizes the analysis process of the preset carbon emission according to the total carbon emission, and improves the monitoring efficiency of the carbon emission.

Specifically, the prediction module compares the obtained building area s0 with a preset area s1, and analyzes preset carbon emission of each stage according to the comparison result, wherein:

when s0 is less than s1, the pre-estimating module sets the preset carbon emission of the material transportation stage as A1, the preset carbon emission of the decoration stage as B1 and the preset carbon emission of the waste treatment stage as C1;

when s0 is greater than or equal to s1, the pre-estimation module sets the preset carbon emission of the material transportation stage as A2, sets A2=A0×A1, sets the preset carbon emission of the decoration stage as B2, sets B2=A0×B1, sets the preset carbon emission of the waste treatment stage as C2, and sets C2=A0×C1, wherein A0 is the calculation result of rounding up s0/s 1.

Specifically, the pre-estimation module improves the accuracy of the pre-set carbon emission analysis of each stage by setting the pre-set area so as to improve the accuracy of the actual carbon emission analysis of each stage, thereby improving the monitoring efficiency of the carbon emission in the building process; in this embodiment, the values of the preset area, A1, B1 and C1 are not specifically limited, and can be freely set by a person skilled in the art, and only the values of the preset area, A1, B1 and C1 are required to be satisfied, wherein the optimal value of the preset area is 50m ² The optimum value of A1 is 300 kg.v.v, v is a carbon-emitting gas, the optimum value of B1 is 100 kg.v, and the optimum value of C1 is 100 kg.v.

Specifically, the transport analysis module determines a carbon emission factor according to the acquired type of the material transport vehicle, and analyzes carbon emissions during a material transport phase according to an analysis result of the transport distance and the carbon emission factor, wherein:

when the material transporting vehicle type is a small-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle as b1, and sets the carbon emission of the vehicle as e1, and sets e1=l1×b1/v;

when the material transporting vehicle type is a medium-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e2, and sets e2=l2×b2/v;

when the material transporting vehicle type is a large-sized vehicle, the transportation analysis module sets the carbon emission factor of the vehicle as b3, and sets the carbon emission of the vehicle as e3, and sets e3=l3×b3/v;

the transportation analysis module sets the carbon emission of the material in the transportation stage as E1, and sets E1=e1+e2+e3, and if E1 is less than or equal to Aa, the transportation analysis module judges that the carbon emission is normal and does not adjust; if E1 > Aa, the transportation analysis module determines that the carbon emission is abnormal and adjusts the preset carbon emission in the decoration stage, and the transportation analysis module sets the adjusted preset carbon emission in the decoration stage as Bb ', and sets Bb' =bb- (E1-Aa);

Wherein v is the fuel efficiency of the vehicle, L1 is the material transportation path of the small-sized vehicle, L2 is the material transportation path of the medium-sized vehicle, and L3 is the material transportation path of the large-sized vehicle.

Specifically, the transportation analysis module improves the accuracy of carbon emission analysis in the material transportation stage by acquiring different vehicle types, and further improves the accuracy of preset carbon emission analysis in the decoration stage, so that the monitoring efficiency of carbon emission in the building process is improved; in this embodiment, the method for obtaining the carbon emission factors and the fuel efficiency is not specifically limited, and a person skilled in the art can freely set the method only by meeting the obtaining requirements of the carbon emission factors and the fuel efficiency, wherein the carbon emission factors and the fuel efficiency can be obtained from a network.

Specifically, the adjusting unit calculates an average speed V0 according to the acquired transportation time t and the material transportation path, compares the calculated result with a preset speed, and adjusts the carbon emission E1 of the material transportation stage according to the comparison result, wherein:

when V0 is less than or equal to V1, the regulating unit judges that the average speed is small, and sets a regulating coefficient alpha 1 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 1 = 1- (V1-V0)/(V1 + V0);

When V1 is smaller than V0 and smaller than V2, the regulating unit judges that the average speed is normal and does not regulate;

when V0 is more than or equal to V2, the regulating unit judges that the average speed is high, and sets a regulating coefficient alpha 2 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 2 = 1+ (V0-V2)/(V2 + V0);

the adjusting unit adjusts the carbon emission E1 of the material transportation stage according to the adjusting coefficient αd, and sets the adjusted carbon emission E1 of the material transportation stage as E1', and sets E1' =e1×αd, d=1, 2;

wherein V1 is a preset minimum speed, and V2 is a preset maximum speed.

Specifically, the adjusting unit sets the preset speed to improve the accuracy of the adjusting coefficient, so that the influence of the transportation speed on the carbon emission of the vehicle is reduced, the accuracy of the analysis of the preset carbon emission in the decoration stage is further improved, and the monitoring efficiency of the carbon emission in the building process is improved; in this embodiment, the value of the preset speed is not specifically limited, and a person skilled in the art can freely set the value of the preset speed only by meeting the value requirement of the preset speed, wherein the optimal value of V1 is 40km/h, and the optimal value of V2 is 80km/h.

Specifically, the correction unit compares the acquired environmental humidity u0 with a preset humidity u1, and corrects the adjustment process of the carbon emission E1 in the material transportation stage according to the comparison result, wherein:

When u0 is less than or equal to u1, the correction unit judges that the humidity is normal and does not correct;

when u0 > u1, the correction means determines that the humidity is abnormal, sets a correction coefficient β to correct the adjustment coefficient αd, sets β=1+ (u 0-u 1)/(u0+u1), sets the corrected adjustment coefficient αd to αd ', and sets αd' =αd×β.

Specifically, the correction unit sets the preset humidity to improve the accuracy of the correction coefficient, so that the influence of the environmental humidity on the carbon emission of the vehicle is reduced, the accuracy of the analysis of the preset carbon emission in the decoration stage is further improved, and the monitoring efficiency of the carbon emission in the building process is improved; in this embodiment, the preset humidity value is not specifically limited, and a person skilled in the art can freely set the preset humidity value only by meeting the preset humidity value requirement, wherein the optimal value of u1 is 60%.

Specifically, the electric power carbon emission analysis unit analyzes the carbon emission of the electric power according to the electric power consumption amount r1, and sets the electric power carbon emission as D1, d1=r1×b4, where b4 is an electric power carbon emission factor.

Specifically, the paint carbon emission analysis unit analyzes carbon emission of the paint according to the obtained VOCs content U and paint mass m in the paint, and sets the paint carbon emission as D2, and sets d2=u×m.

Specifically, the decoration carbon emission analysis unit analyzes carbon emissions in a decoration stage according to an analysis result of electric power carbon emissions and paint carbon emissions, and sets the second stage carbon emissions to E2, and sets e2=d1+d2, wherein:

when E1 is less than or equal to Aa, if E2 is less than or equal to Bb, the decoration carbon emission analysis unit judges that the carbon emission is normal, and no adjustment is performed; if E2 > Bb, the decoration carbon emission analysis unit determines that the carbon emission is abnormal, and adjusts the preset carbon emission of the waste treatment stage, and the decoration carbon emission analysis unit sets the preset carbon emission of the adjusted waste treatment stage as Cc ', and sets Cc' =cc- (E2-Bb);

when E1 > Aa, if E2 is less than or equal to Bb', the decoration carbon emission analysis unit judges that the carbon emission is normal; if E2 > Bb ', the finishing carbon emission analysis unit determines that the carbon emission is abnormal and adjusts the preset carbon emission in the waste treatment stage, and the finishing carbon emission analysis unit sets the adjusted preset carbon emission in the waste treatment stage as Cc', and sets Cc '=cc- (E2-Bb').

Specifically, the decoration carbon emission unit sums the electric carbon emission and the paint carbon emission and compares the electric carbon emission with the preset carbon emission in the preset decoration stage, so that the accuracy of the analysis of the preset carbon emission in the waste treatment stage is improved, and the monitoring efficiency of the carbon emission in the building process is improved.

Specifically, the correction unit compares the acquired ambient temperature t0 with each preset temperature, and corrects the adjustment process of the preset carbon emission in the waste treatment stage according to the comparison result, wherein:

when t0 < t1, the correction unit determines that the ambient temperature is low, and sets a correction coefficient H1 to correct the preset carbon emission Cc' of the waste treatment stage, and sets h1=1+ (t 1-t 0)/(t1+t0);

when t1 is less than or equal to t0 and less than or equal to t2, the correction unit judges that the ambient temperature is normal and does not correct;

when t0 is more than or equal to t2, the correction unit judges that the ambient temperature is high, sets a correction coefficient H2 to correct the preset carbon emission Cc' of the waste treatment stage, and sets H2+ (t 0-t 2)/(t2+t0);

the correction unit corrects the preset carbon emission Cc ' of the waste treatment stage according to the correction coefficient Hh, and sets the corrected preset carbon emission Cc ' of the waste treatment stage as Cc ", sets Cc" =cc ' ×hh, and sets h=1, 2;

wherein t1 is a preset minimum temperature, and t2 is a preset maximum temperature.

Specifically, the correction unit sets the preset temperature to improve the accuracy of the correction coefficient, so that the influence of the environmental temperature on the decoration carbon emission is reduced, the accuracy of the analysis of the preset carbon emission in the waste treatment stage is further improved, and the monitoring efficiency of the carbon emission in the building process is improved; in this embodiment, the value of the preset temperature is not specifically limited, and a person skilled in the art can freely set the value of the preset temperature only by meeting the value requirement of the preset temperature, wherein the optimal value of t1 is 10 degrees, and the optimal value of t2 is 30 degrees.

Specifically, the compensation unit compares the obtained precipitation amount p0 during decoration with a preset precipitation amount p1, and compensates a correction process of an adjustment process of the preset carbon emission of the waste treatment stage according to the comparison result, wherein:

when p0 is less than p1, the compensation unit judges that the precipitation is normal and does not compensate;

when p0 is greater than or equal to p1, the compensation unit determines that the precipitation is abnormal, sets a compensation coefficient as k, sets k=1- (p 0-p 1)/(p0+p1), compensates the correction coefficient H2 according to the compensation coefficient k, sets the compensated correction coefficient H2 as H2', and sets H2' =h2×k.

Specifically, the compensation unit sets the preset precipitation amount to improve the accuracy of the compensation coefficient, so that the influence of the precipitation amount on decoration carbon emission is reduced, the accuracy of analysis of the preset carbon emission in the waste treatment stage is further improved, and the monitoring efficiency of carbon emission in the building process is improved; in this embodiment, the preset precipitation amount is not specifically limited, and a person skilled in the art can freely set the preset precipitation amount only by meeting the preset precipitation amount requirement, wherein the optimal value of p1 is 50mm in summer.

Specifically, the waste analysis module determines a carbon emission factor according to the acquired type of waste transport vehicle, and analyzes carbon emissions during a material transport phase according to an analysis result of the transport distance and the carbon emission factor, wherein:

When the type of the waste transport vehicle is a small car, the waste analysis module sets the carbon emission factor of the vehicle to b1, and the carbon emission of the vehicle to e4, and sets e4=l4×b1/v;

when the type of the waste transport vehicle is a medium-sized vehicle, the waste analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e5, setting e5=l5×b2/v;

when the type of the waste transport vehicle is a large-sized vehicle, the waste analysis module sets the carbon emission factor of the vehicle to b3, and sets the carbon emission of the vehicle to e6, and sets e6=l6×b3/v;

the carbon emission of the waste treatment stage is set as E3 by the waste analysis module, and E3 = E4+ E5+ E6 is set, wherein L4 is the waste transportation path of the small-sized vehicle, L5 is the waste transportation path of the medium-sized vehicle, and L6 is the waste transportation path of the large-sized vehicle.

Specifically, the transportation analysis module improves the accuracy of carbon emission analysis in the waste stage by acquiring different vehicle types, thereby improving the monitoring efficiency of carbon emission in the building process.

Specifically, the monitoring module compares the analysis result of the carbon emission of each stage with the preset carbon emission of each stage, and performs early warning according to the comparison result, wherein:

When E1 is less than or equal to Aa in the material transportation stage, the monitoring module judges that the carbon emission is normal in the material transportation stage, early warning is not carried out, and when E1 is more than Aa, the monitoring module judges that the carbon emission is excessive in the material transportation stage, and early warning is carried out;

when E1 is less than or equal to Aa and less than or equal to Bb in the decoration stage, the monitoring module judges that the carbon emission is normal in the decoration stage, early warning is not carried out, and when E2 is more than Bb, the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out; when E1 is more than Aa, if E2 is less than or equal to Bb ', the monitoring module judges that the carbon emission is normal in the decoration stage, no early warning is carried out, and if E2 is more than Bb', the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out;

in the waste treatment stage, when E2 is less than or equal to Bb or E2 is less than or equal to Bb', if E3 is less than or equal to Cc, the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is more than Cc, the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out; when E2 is larger than Bb or E2 is larger than Bb ', if E3 is smaller than or equal to Cc ', the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is larger than Cc ', the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out.

Specifically, the monitoring module pre-warns abnormal carbon emission according to analysis results of carbon emission in each stage, so that control of carbon emission by technicians is improved, an original working mode can be replaced by a mode with less carbon emission, and monitoring efficiency of carbon emission in a building process is improved.

Specifically, the optimization module sums the carbon emissions of the stages to obtain a total carbon emission E _{Real world} And with the sum E of the respective preset carbon emissions _{Pre-preparation} Comparing, and optimizing an analysis process of the preset carbon emission of each building stage according to the comparison result, wherein:

when E is _{Real world} ≤E _{Pre-preparation} When the total carbon emission is normal, the optimization module judges that the total carbon emission is not optimized;

when E is _{Real world} ＞E _{Pre-preparation} If (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} J is less than or equal to, the optimization module judges that the total carbon emission is normal, and optimization is not performed; if (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} The optimizing module judges that the total carbon emission is abnormal and sets an optimizing coefficient gamma to optimize the preset carbon emission of each building stage of each stage, and sets gamma=1+ (E _{Real world} -E _{Pre-preparation} )/(E _{Real world} +E _{Pre-preparation} ) The method includes setting a preset carbon emission Aa of an optimized material transportation stage to Aa1, setting aa1=aa×γ, setting a preset carbon emission Bb of an optimized finishing stage to Bb1, setting bb1=bb×γ, setting a preset carbon emission Cc of an optimized waste material treatment stage to Cc1, and setting cc1=cc×γ.

Specifically, the optimization module sets a sum E of preset carbon emissions _{Pre-preparation} The accuracy of the optimization coefficient is improved, and the accuracy of the analysis of the preset carbon emission in each stage is further improved, so that the monitoring efficiency of the carbon emission in the building process is improved, and the monitoring efficiency of the carbon emission in the building process is improved; in the present embodiment, the E is not _{Pre-preparation} The value of (2) is specifically limited, and can be freely set by a person skilled in the art by only meeting the value requirement of the preset temperature, wherein E _{Pre-preparation} The optimum value of (2) is 500 kg. V.

Thus far, the technical solution of the present invention has been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of protection of the present invention is not limited to these specific embodiments. Equivalent modifications and substitutions for related technical features may be made by those skilled in the art without departing from the principles of the present invention, and such modifications and substitutions will be within the scope of the present invention.

Claims (10)

1. A carbon emission monitoring system in a building process is characterized by comprising,

the information acquisition module is used for acquiring building information, transportation information, energy consumption information, environment information and paint information;

the pre-estimating module is used for analyzing the preset carbon emission of the material transportation stage, the decoration stage and the waste treatment stage according to the acquired building area;

the transport analysis module is used for analyzing the carbon emission of the material transport stage according to the type of the obtained material transport vehicle and the material transport distance, and adjusting the preset carbon emission of the decoration stage according to the analysis result;

The adjusting module is used for adjusting the analysis process of the carbon emission in the material transportation stage according to the acquired transportation time and the acquired environmental humidity;

the decoration analysis module is used for analyzing the carbon emission in the decoration stage according to the adjustment result of the transportation analysis module on the preset carbon emission in the decoration stage, the acquired electric energy consumption, the content of VOCs in the paint and the quality of the paint, and adjusting the preset carbon emission in the waste treatment stage according to the analysis result;

the correction module is used for correcting the adjustment process of the preset carbon emission in the waste treatment stage according to the acquired ambient temperature and precipitation;

the waste analysis module is used for analyzing the carbon emission of the waste treatment stage according to the adjustment result of the decoration analysis module on the preset carbon emission of the waste treatment stage, the type of the obtained waste transport vehicle and the waste transport distance;

the monitoring module is used for carrying out early warning according to the analysis result of the carbon emission of each stage;

and the optimizing module is used for optimizing the analysis process of the preset carbon emission according to the analysis result of the carbon emission of each stage.

2. The in-building carbon emission monitoring system of claim 1, wherein the pre-estimation module compares the obtained building area s0 with a preset area s1, and analyzes the preset carbon emission of each stage according to the comparison result, wherein:

When s0 is less than s1, the pre-estimating module sets the preset carbon emission of the material transportation stage as A1, the preset carbon emission of the decoration stage as B1 and the preset carbon emission of the waste treatment stage as C1;

when s0 is greater than or equal to s1, the pre-estimation module sets the preset carbon emission of the material transportation stage as A2, sets a2=a0×a1, sets the preset carbon emission of the decoration stage as B2, sets b2=a0×b1, sets the preset carbon emission of the waste treatment stage as C2, and sets c2=a0×c1.

3. The in-building carbon emission monitoring system of claim 2, wherein the transport analysis module determines a carbon emission factor based on the acquired material transport vehicle type pair and analyzes carbon emissions during a material transport phase based on an analysis result of the transport distance and the carbon emission factor, wherein:

when the material transporting vehicle type is a small-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle as b1, and sets the carbon emission of the vehicle as e1, and sets e1=l1×b1/v;

when the material transporting vehicle type is a medium-sized vehicle, the transport analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e2, and sets e2=l2×b2/v;

When the material transporting vehicle type is a large-sized vehicle, the transportation analysis module sets the carbon emission factor of the vehicle as b3, and sets the carbon emission of the vehicle as e3, and sets e3=l3×b3/v;

the transportation analysis module sets the carbon emission of the material in the transportation stage as E1, and sets E1=e1+e2+e3, and if E1 is less than or equal to Aa, the transportation analysis module judges that the carbon emission is normal and does not adjust; if E1 > Aa, the transport analysis module determines that the carbon emission is abnormal and adjusts the preset carbon emission in the decoration stage, and the transport analysis module sets the adjusted preset carbon emission in the decoration stage as Bb ', and sets Bb' =bb- (E1-Aa).

4. The in-building carbon emission monitoring system according to claim 3, wherein the adjustment module is provided with an adjustment unit, the adjustment unit calculates an average speed V0 according to the acquired transportation time t and the material transportation path, compares the calculation result with a preset speed, and adjusts the carbon emission E1 in the material transportation stage according to the comparison result, wherein:

when V0 is less than or equal to V1, the regulating unit judges that the average speed is small, and sets a regulating coefficient alpha 1 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 1 = 1- (V1-V0)/(V1 + V0);

When V1 is smaller than V0 and smaller than V2, the regulating unit judges that the average speed is normal and does not regulate;

when V0 is more than or equal to V2, the regulating unit judges that the average speed is high, and sets a regulating coefficient alpha 2 to regulate the carbon emission E1 of the material in the transportation stage, and alpha 2 = 1+ (V0-V2)/(V2 + V0);

the adjusting unit adjusts the carbon emission E1 of the material transportation stage according to the adjusting coefficient αd, and sets the adjusted carbon emission E1 of the material transportation stage as E1', and sets E1' =e1×αd, d=1, 2;

the adjustment module is also provided with a correction unit, the correction unit compares the acquired ambient humidity u0 with preset humidity u1 and corrects the adjustment process of the carbon emission E1 in the material transportation stage according to the comparison result, wherein:

when u0 is less than or equal to u1, the correction unit judges that the humidity is normal and does not correct;

when u0 > u1, the correction means determines that the humidity is abnormal, sets a correction coefficient β to correct the adjustment coefficient αd, sets β=1+ (u 0-u 1)/(u0+u1), sets the corrected adjustment coefficient αd to αd ', and sets αd' =αd×β.

5. The in-building carbon emission monitoring system according to claim 1, wherein the decoration analysis module is provided with an electric carbon emission analysis unit that analyzes carbon emission of electric power according to an electric energy consumption amount r1, the electric carbon emission analysis unit sets the electric carbon emission as D1, d1=r1×b4, where b4 is an electric carbon emission factor, and the decoration analysis module is provided with a paint carbon emission analysis unit that analyzes carbon emission of paint according to an acquired paint content U of VOCs and paint quality m, the paint carbon emission analysis unit sets the paint carbon emission as D2, and d2=u× m.

6. The in-building carbon emission monitoring system according to claim 5, wherein the decoration analysis module is provided with a decoration carbon emission analysis unit that analyzes carbon emissions in a decoration stage according to an analysis result of electric power carbon emissions and paint carbon emissions, the decoration carbon emission analysis unit sets E2 as second-stage carbon emissions, and e2=d1+d2 is set, wherein:

when E1 is less than or equal to Aa, if E2 is less than or equal to Bb, the decoration carbon emission analysis unit judges that the carbon emission is normal, and no adjustment is performed; if E2 > Bb, the decoration carbon emission analysis unit determines that the carbon emission is abnormal, and adjusts the preset carbon emission of the waste treatment stage, and the decoration carbon emission analysis unit sets the preset carbon emission of the adjusted waste treatment stage as Cc ', and sets Cc' =cc- (E2-Bb);

when E1 > Aa, if E2 is less than or equal to Bb', the decoration carbon emission analysis unit judges that the carbon emission is normal; if E2 > Bb ', the finishing carbon emission analysis unit determines that the carbon emission is abnormal and adjusts the preset carbon emission in the waste treatment stage, and the finishing carbon emission analysis unit sets the adjusted preset carbon emission in the waste treatment stage as Cc', and sets Cc '=cc- (E2-Bb').

7. The in-building carbon emission monitoring system according to claim 6, wherein the correction module is provided with a correction unit that compares the acquired ambient temperature t0 with each preset temperature and corrects the adjustment process of the preset carbon emission in the waste treatment stage according to the comparison result, wherein:

when t0 < t1, the correction unit determines that the ambient temperature is low, and sets a correction coefficient H1 to correct the preset carbon emission Cc' of the waste treatment stage, and sets h1=1+ (t 1-t 0)/(t1+t0);

when t1 is less than or equal to t0 and less than or equal to t2, the correction unit judges that the ambient temperature is normal and does not correct;

when t0 is more than or equal to t2, the correction unit judges that the ambient temperature is high, sets a correction coefficient H2 to correct the preset carbon emission Cc' of the waste treatment stage, and sets H2+ (t 0-t 2)/(t2+t0);

the correction unit corrects the preset carbon emission Cc ' of the waste treatment stage according to the correction coefficient Hh, and sets the corrected preset carbon emission Cc ' of the waste treatment stage as Cc ", sets Cc" =cc ' ×hh, and sets h=1, 2;

the correction module is also provided with a compensation unit, the compensation unit compares the acquired precipitation p0 during decoration with a preset precipitation p1 and compensates the correction process of the adjustment process of the preset carbon emission of the waste treatment stage according to the comparison result, wherein:

When p0 is less than p1, the compensation unit judges that the precipitation is normal and does not compensate;

when p0 is greater than or equal to p1, the compensation unit determines that the precipitation is abnormal, sets a compensation coefficient as k, sets k=1- (p 0-p 1)/(p0+p1), compensates the correction coefficient H2 according to the compensation coefficient k, sets the compensated correction coefficient H2 as H2', and sets H2' =h2×k.

8. The in-building carbon emission monitoring system of claim 1, wherein the waste analysis module determines a carbon emission factor based on the acquired waste transport vehicle type pair and analyzes carbon emissions during a material transport phase based on a transport distance and an analysis result of the carbon emission factor, wherein:

when the type of the waste transport vehicle is a small car, the waste analysis module sets the carbon emission factor of the vehicle to b1, and the carbon emission of the vehicle to e4, and sets e4=l4×b1/v;

when the type of the waste transport vehicle is a medium-sized vehicle, the waste analysis module sets the carbon emission factor of the vehicle to b2, and sets the carbon emission of the vehicle to e5, setting e5=l5×b2/v;

when the type of the scrap transporting vehicle is a large-sized vehicle, the scrap analyzing module sets the carbon emission factor of the vehicle to b3 and the carbon emission of the vehicle to e6, and sets e6=l6×b3/v.

9. The in-building carbon emission monitoring system of claim 1, wherein the monitoring module compares the analysis result of the carbon emission of each stage with a preset carbon emission of each stage, and performs early warning according to the comparison result, wherein:

when E1 is less than or equal to Aa in the material transportation stage, the monitoring module judges that the carbon emission is normal in the material transportation stage, early warning is not carried out, and when E1 is more than Aa, the monitoring module judges that the carbon emission is excessive in the material transportation stage, and early warning is carried out;

when E1 is less than or equal to Aa and less than or equal to Bb in the decoration stage, the monitoring module judges that the carbon emission is normal in the decoration stage, early warning is not carried out, and when E2 is more than Bb, the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out; when E1 is more than Aa, if E2 is less than or equal to Bb ', the monitoring module judges that the carbon emission is normal in the decoration stage, no early warning is carried out, and if E2 is more than Bb', the monitoring module judges that the carbon emission is excessive in the decoration stage, and early warning is carried out;

in the waste treatment stage, when E2 is less than or equal to Bb or E2 is less than or equal to Bb', if E3 is less than or equal to Cc, the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is more than Cc, the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out; when E2 is larger than Bb or E2 is larger than Bb ', if E3 is smaller than or equal to Cc ', the monitoring module judges that the carbon emission of the waste treatment module is normal, early warning is not carried out, and if E3 is larger than Cc ', the monitoring module judges that the carbon emission of the waste treatment module is excessive, and early warning is carried out.

10. The in-building carbon emissions monitoring system of claim 2, wherein the optimization module sums the stage carbon emissions to obtain a total carbon emission E _{Real world} And with the sum E of the respective preset carbon emissions _{Pre-preparation} Comparing, and optimizing an analysis process of the preset carbon emission of each building stage according to the comparison result, wherein:

when E is _{Real world} ≤E _{Pre-preparation} When the total carbon emission is normal, the optimization module judges that the total carbon emission is not optimized;

when E is _{Real world} ＞E _{Pre-preparation} If (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} J is less than or equal to, the optimization module judges that the total carbon emission is normal, and optimization is not performed; if (E) _{Real world} -E _{Pre-preparation} )/E _{Pre-preparation} The optimizing module judges that the total carbon emission is abnormal and sets an optimizing coefficient gamma to optimize the preset carbon emission of each building stage of each stage, and sets gamma=1+ (E _{Real world} -E _{Pre-preparation} )/(E _{Real world} +E _{Pre-preparation} ) The method includes setting a preset carbon emission Aa of an optimized material transportation stage to Aa1, setting aa1=aa×γ, setting a preset carbon emission Bb of an optimized finishing stage to Bb1, setting bb1=bb×γ, setting a preset carbon emission Cc of an optimized waste material treatment stage to Cc1, and setting cc1=cc×γ.