KR102575542B1 - Thermal energy and electricity supply management system using biomass livestock manure solid fuel - Google Patents

Abstract

The present invention relates to a thermal energy and electricity supply management system using a biomass livestock manure solid fuel, and more specifically, to a thermal energy and electricity supply management system using a biomass livestock manure solid fuel which provides steam energy based on solid fuels using eco-friendly and low carbon livestock manure, and services and management for the same. The thermal energy and electricity supply management system using a biomass livestock manure solid fuel comprises: a fuel information management unit which interconnects with a server for National Agricultural/ livestock Cooperative Federations to transmit and receive biomass fuel supplying data; an energy information building unit which builds a biomass fuel converting energy database; a transaction cost producing unit which produces a biomass fuel converting energy transaction cost according to the database built by the energy information building unit; and a transaction feedback unit which produces carbon reduction result data according to biomass energy, based on the data built by the energy information building unit and the transaction cost producing unit to provide a feedback to the transaction cost producing unit and the fuel information management unit.

Description

Thermal energy and electricity supply management system using biomass livestock manure solid fuel}

The present invention relates to a thermal energy and electricity supply management system using biomass livestock manure solid fuel, and more particularly, to provide steam energy based on solid fuel using eco-friendly low-carbon livestock manure, thermal energy using biomass livestock manure solid fuel for service and management and an electricity supply management system.

As the domestic livestock industry grows, the amount of livestock manure is also increasing every year. According to the National Statistical Office, as of 2020, the livestock production amount is 20,122.7 billion won. From 1965 to 2018, it increased by about 12.2% per year on average for 54 years. The amount of livestock manure is also increasing every year, and the amount generated in 2020 was 51.94 million tons, an increase of about 4.95 million tons within 5 years.

Therefore, Rural Development Administration is currently developing technologies to process livestock manure to create energy or reduce greenhouse gas emissions. Manure collected from livestock farms is usually separated into solid and liquid through a treatment facility, and is made into solid and liquid fertilizers, respectively. In October of last year, the Rural Development Administration created a system that recovers and recycles the heat generated during the fermentation of liquid fertilizer. The system collects waste heat and uses it as warm air to dry solid fertilizer or uses it as heating energy for barns and facility houses.

In addition, technology from private companies is also used for energy conversion of livestock manure. It is possible to expand the production of new and renewable energy using livestock manure based on information and communication technology (ICT) and the Internet of Things (IoT) of private companies. The technology turns livestock manure, such as cow dung, into highly efficient solid fuel through a pyrohydrolysis process. The solid fueled cow manure can be used as a new and renewable energy source in steel mills and the like. In particular, it is analyzed that about 300,000 tons of carbon dioxide can be saved annually if 2.2 million tons, or 10% of cow manure production, is converted into solid fuel and supplied. In addition, it can be used as an energy source for electricity, green hydrogen, and biomethane by improving the quality of methane gas generated in the manure treatment process. Methane gas has a high calorific value and can be used as a fuel for power plants that produce energy such as electricity. If 150 tons of manure is processed daily at the livestock manure energy facility, 22,000 tons of greenhouse gases can be reduced annually. In addition, it can produce 5768MWh of electricity per year, which corresponds to the electricity consumption of about 1900 households based on four-person households.

Therefore, according to the prior invention, as in Korea Patent Publication No. 2021-0147500 (hereinafter referred to as Patent Document 0001) according to the increase in the need for electricity supply and management system technology generated from low-carbon fuel based on livestock manure as above, fuel cell power generation Technologies are being developed to provide monitoring and control systems and methods.

In other words, by establishing a monitoring system at the power consumer, accessing the power statistics system of the Korea Power Exchange to monitor the current status of power supply and demand and system limit price (SMP) in real time, and at the same time providing various operation information data such as fuel cell generation amount information and heat amount information. It monitors and, based on this, provides technology related to fuel cell power generation monitoring and control systems and methods that control fuel cell power generation.

More specifically, the fuel cell's real-time today's power generation/cumulative power generation amount is converted into money and shown, and the fuel cell according to the power market price of the power exchange by utilizing the rate system used by KEPCO and power usage prediction data. We are providing a new type of fuel cell power generation monitoring and control system technology to save electricity and gas rates as much as possible by operating the fuel cell power generation profit in stages and operating the fuel cell system efficiently.

However, in the case of the recently developed biomass fuel conversion energy supply management system, the biomass heating energy ratio calculation method, the tax calculation method according to the calculation of the reduced carbon dioxide amount due to biomass heating, and the additional power consumption There is a problem that there is a technical limitation in automatically calculating and managing the additional fuel supply cost according to the measurement of greenhouse gas emissions according to the method.

Korean Patent Publication No. 2021-0147500 (2021.12.07.) Korean Registered Patent Publication No. 10-1803919 (2017.11.27.) Korean Patent Publication No. 2011-0085748 (2011.07.27.)

The present invention takes into account such problems, and the present invention receives biomass solid fuel based on the EPC O&M management system, calculates and receives the received biomass solid fuel cost, and provides biomass steam energy service (rental) to customers. ) to provide a thermal energy and electricity supply management system using biomass livestock solid fuel that manages a series of processes.

Thermal energy and electricity supply management system using biomass solid fuel according to embodiments of the present invention is a biomass energy transaction monitoring device, comprising: a fuel information management unit that transmits and receives biomass fuel supply data in conjunction with the National Agricultural Cooperative Federation server; An energy information construction unit that builds a biomass fuel conversion energy database; a transaction cost calculation unit for calculating a biomass fuel conversion energy transaction cost according to the database built in the energy information establishment unit; Based on the data constructed by the energy information construction unit and the transaction cost calculation unit, a transaction feedback unit that calculates carbon reduction result data according to biomass energy and feeds back to the transaction cost calculation unit and the fuel information management unit; .

In embodiments of the present invention, the biomass energy transaction monitoring device is characterized by real-time monitoring of biomass fuel supply transaction data based on SCADA (Supervisory Control and Data Acquisition) industrial control system.

In embodiments of the present invention, the biomass energy transaction monitoring device is characterized by real-time monitoring of measured values of a steam pressure gauge, a steam flowmeter, a steam thermometer, a water supply temperature gauge, an electricity meter, and a biomass meter.

In the embodiments of the present invention, the fuel information management unit receives biomass fuel supply data in conjunction with the regional agricultural cooperative server to build a fuel supply quantity database; a fuel transaction cost calculation transmission unit that calculates fuel transaction cost according to the biomass fuel supply amount data received by the fuel data receiving unit, constructs fuel transaction amount cost data, and transmits the data to the regional agricultural cooperative server; A fuel data update unit configured to update the fuel supply amount database and the fuel transaction amount cost data in real time according to the biomass fuel supply data change amount.

In the embodiments of the present invention, the fuel data update unit updates biomass energy transaction monitoring device inspection, biomass fuel supply amount data inspection, biomass fuel validation test date data, and updates biofuel test start date data. It is characterized in that the expiration date data of the biofuel test is automatically updated according to the biofuel test.

In the embodiments of the present invention, the energy information construction unit includes an energy DB unit for constructing a database by calculating the amount of biomass fuel conversion energy according to the biomass fuel supply amount, and the biomass fuel conversion energy is biomass fuel conversion energy. Characterized in that it is mass steam energy.

In embodiments of the present invention, the biomass energy transaction monitoring device is characterized by real-time monitoring of biomass fuel supply transaction data based on SCADA (Supervisory Control and Data Acquisition) industrial control system.

In embodiments of the present invention, the biomass energy transaction monitoring device is characterized by real-time monitoring of measured values of a steam pressure gauge, a steam flowmeter, a steam thermometer, a water supply temperature gauge, an electricity meter, and a biomass meter.

In embodiments of the present invention, the energy DB unit is characterized in that the amount of biomass fuel conversion energy according to the biomass fuel supply is calculated by the following formula. here, is the baseline heat release (tCO2/annum) of the biomass fuel boiler, is biomass fuel boiler heating energy (GJ/ton), Silver biomass fuel heating facility efficiency (%), is the biomass fuel boiler feedwater energy in GJ/ton.

In embodiments of the present invention, the energy information construction unit energy database containing biomass steam energy business related information based on the data collected by the energy DB unit; And an energy transaction DB unit that manages; an energy transaction database containing data on the amount of energy traded by the biomass steam energy customer.

In embodiments of the present invention, the energy account database includes biomass steam energy account name, representative name, address, phone number and fax number, e-mail address, transaction manager name and direct number or email address of the person in charge.

In embodiments of the present invention, the transaction cost calculation unit calculates the biomass steam energy supply cost per month for each biomass steam energy customer based on the amount of energy traded by the biomass steam energy customer.

In the embodiments of the present invention, the transaction feedback unit calculates the carbon reduction result data by calculating greenhouse gas emissions according to calorimetry after business based on the data built in the energy information construction unit and the transaction cost calculation unit. It is characterized by doing.

In the embodiments of the present invention, the greenhouse gas emissions according to the calorimetric measurement after the project are the leakage emissions of biomass residue in year y, and are characterized in that they are calculated by the following equation. here, y-year leakage emissions of silver biomass residues (tCO2/yr); is the CO2 emission factor of the most carbon-intensive fossil fuel used in the country (tCO2/GJ), is the amount of biomass used and included within the project boundary (tons); is the net calorific value (GJ/yr*Tons) of the biomass residue in category n in year y.

In the embodiments of the present invention, the transaction feedback unit calculates the amount of greenhouse gas emission reduction according to the amount of greenhouse gas emission according to the calorimetry after the business and feeds back the carbon reduction result data to the transaction cost calculation unit. do.

In embodiments of the present invention, the transaction feedback unit is characterized in that the greenhouse gas emission reduction amount is calculated by the following formula. ; ; here, is the project emissions from burning fossil fuels in process j in year y (tCO2/yr), is the amount of I fuel burned in process j in year y (Tons/yr), is the weighted average net calorific value of fuel i in year y (GJ/kg), is the weighted average CO2 emission factor of fuel i in year y (tCO2/GJ), is the CO2 emission factor of fuel i in year y (tCO2/kg).

In embodiments of the present invention, the transaction feedback unit is characterized in that it feeds back to the fuel information management unit to control the biomass fuel supply amount according to the amount of greenhouse gas emission reduction.

According to the thermal energy and electricity supply management system using biomass livestock solid fuel as described above, the following effects are obtained.

First, it is possible to collect data through SCADA (Supervisory Control and Data Acquisition) and PC, and to classify and systematize data.

Second, it is possible to build a DB by collecting various data generated during boiler O&M, and through the DB, it is possible to automatically calculate the monthly cost of using steam energy, and to manage the control of livestock manure fuel supply according to carbon dioxide reduction or carbon dioxide emission. can

Third, it is possible to monitor the electricity supply and demand status of electricity transaction and system marginal price (SMP) in real time, and at the same time, various operation information data such as biomass fuel cell power generation information and calorific value information can be monitored in real time.

Fourth, when fuel is solidified, a high-speed fermenter method is adopted, and when livestock manure is put into the high-speed fermentor, carbon-reduction patented microorganisms are stirred together to reduce odor generation, thereby fundamentally solving the complaints of local residents.

Fifth, since livestock manure is not treated as waste but recycled as fuel, the problem of total water quality in each region can be solved.

Sixth, the number of breeding heads can be increased to respond to meat consumption, and the improvement of the total water quality system can induce companies to attract local industrial complexes.

Seventh, at a time when LPG and LNG prices skyrocketed, it can help local manufacturing companies operating biomass livestock meal solid fuel industrial steam boilers improve their financial soundness and secure local government tax revenue.

1 is a configuration diagram of the present invention.
2 is a schematic diagram of the present invention.
3 is a schematic diagram of a fuel information management unit 10 according to an embodiment of the present invention.
4 is a configuration diagram of the energy information construction unit 20 according to an embodiment of the present invention.
5 is a configuration diagram showing a feedback flow of the transaction feedback unit 30 according to an embodiment of the present invention.

Referring to the accompanying drawings, a biomass livestock meal solid fuel utilization management system for thermal energy and electricity supply according to embodiments of the present invention will be described in detail. Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure. In the accompanying drawings, the dimensions of the structures are shown enlarged than actual for clarity of the present invention, or reduced than actual in order to understand the schematic configuration.

Also, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. Meanwhile, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

The present invention relates to a thermal energy and electricity supply management system using biomass livestock manure solid fuel, and more particularly, to provide steam energy based on solid fuel using eco-friendly low-carbon livestock manure, thermal energy using biomass livestock manure solid fuel for service and management and an electricity supply management system.

1 is a configuration diagram of the present invention, and FIG. 2 is a schematic diagram of the present invention.

Referring to FIG. 1, the system for managing the supply of thermal energy and electricity using biomass livestock solid fuel includes a fuel information management unit 10, an energy information construction unit 20, a transaction cost calculation unit 30, and a transaction feedback unit 40. do. In the biomass energy transaction monitoring device, the fuel information management unit 10 transmits and receives biomass fuel supply data in conjunction with the National Agricultural Cooperative Federation server. Here, the biomass energy transaction monitoring device monitors biomass fuel supply transaction data based on the industrial control system SCADA (Supervisory Control and Data Acquisition) in real time. In addition, it monitors the measured values of the steam pressure gauge, steam flowmeter, steam thermometer, feed water thermometer, watt-hour meter, and biomass meter in real time. Thereafter, the energy information construction unit 20 builds a biomass fuel conversion energy database, and the transaction cost calculation unit 30 calculates the biomass fuel conversion energy transaction cost according to the database built in the energy information construction unit 20. . In more detail, the transaction cost calculation unit 30 calculates the biomass steam energy supply cost per month for each biomass steam energy customer based on the amount of energy traded by the biomass steam energy customer. Thereafter, the transaction feedback unit 40 calculates carbon reduction result data according to biomass energy based on the data built in the energy information construction unit 20 and the transaction cost calculation unit 30, and the transaction cost calculation unit 30 And it feeds back to the fuel information management unit 10.

3 is a schematic diagram of a fuel information management unit 10 according to an embodiment of the present invention.

Referring to FIG. 3 , the fuel information management unit 10 includes a fuel data receiver 10a, a fuel transaction cost calculation transmitter 10b, and a fuel data update unit 10c. The fuel data receiving unit 10a receives biomass fuel supply data in conjunction with the regional agricultural cooperative server to build a fuel supply amount database, and the fuel transaction cost calculation transmitter 10b calculates the biomass received by the fuel data receiver 10a. The fuel transaction amount cost data according to the fuel supply amount data is calculated, the fuel transaction amount cost data is constructed, and the fuel transaction amount cost data is transmitted to the regional agricultural cooperative server. Thereafter, the fuel data update unit 10c stores the fuel supply amount database and the fuel transaction amount cost data in real time according to the biomass fuel supply data change amount measured from each of the steam pressure gauge, the steam flow meter, the steam thermometer, the feed water thermometer, the electricity meter, and the biomass meter. update does. In addition, the fuel data update unit 10c updates the biomass energy transaction monitoring device inspection, biomass fuel supply amount data inspection, and biomass fuel validation test date data, and updates the biofuel test start date data. It is characterized in that the expiration date data of the test is automatically updated.

4 is a configuration diagram of the energy information construction unit 20 according to an embodiment of the present invention.

Referring to FIG. 4 , the energy information construction unit 20 includes an energy DB unit 20a and an energy transaction DB unit 20b. The energy DB unit 20a calculates the amount of biomass fuel conversion energy according to the amount of biomass fuel supplied and builds a database. Here, the biomass fuel conversion energy is biomass steam energy.

The energy DB unit 20a according to the embodiment is characterized by calculating the amount of biomass fuel conversion energy according to the amount of biomass fuel supplied by the following formula. The expression below is am. here, is the baseline heat release (tCO2/annum) of the biomass fuel boiler, is biomass fuel boiler heating energy (GJ/ton), Silver biomass fuel heating facility efficiency (%), is the biomass fuel boiler feedwater energy in GJ/ton.

In the case of the energy trading DB unit 20b according to the embodiment, the energy trading database including information related to biomass steam energy trading partners based on the data collected in the energy DB unit 20a and the amount of energy traded by the biomass steam energy trading partners Manages the energy transaction volume database containing data. In more detail, the energy account database includes biomass steam energy account name, representative name, address, phone number and fax number, e-mail address, transaction manager name and direct number or email address of the person in charge.

5 is a configuration diagram showing a feedback flow of the transaction feedback unit 40 according to an embodiment of the present invention. Referring to FIG. 5, the transaction feedback unit 40 calculates greenhouse gas emissions according to calorimetry after the project based on the data built in the energy information construction unit 20 and the transaction cost calculation unit 30 to reduce the carbon The resulting data is calculated and fed back to the transaction cost calculation unit 30 and the fuel information management unit 10 .

To explain in more detail, the greenhouse gas emission according to calorimetry after the project is the leakage emission of biomass residue in year y, and is calculated by the following equation. The expression below is is, where y-year leakage emissions of silver biomass residues (tCO2/yr); is the CO2 emission factor of the most carbon-intensive fossil fuel used in the country (tCO2/GJ), is the amount of biomass used and included within the project boundary (tons); is the net calorific value (GJ/yr*Tons) of the biomass residue in category n in year y.

In addition, the transaction feedback unit 40 feeds back the carbon reduction result data to the transaction cost calculation unit 30 for the amount of greenhouse gas emission reduction according to the amount of greenhouse gas emissions calculated according to the caloric measurement after the business. Here, the transaction feedback unit 40 calculates the greenhouse gas emission reduction amount by the following equation. The expression below is ego, am. here, is the project emissions from burning fossil fuels in process j in year y (tCO2/yr), is the amount of I fuel burned in process j in year y (Tons/yr), is the weighted average net calorific value of fuel i in year y (GJ/kg), is the weighted average CO2 emission factor of fuel i in year y (tCO2/GJ), is the CO2 emission factor of fuel i in year y (tCO2/kg). Thereafter, it is fed back to the fuel information management unit 10 to control the biomass fuel supply amount according to the greenhouse gas emission reduction amount.

Here, it is mandatory to install odor reduction facilities and equipment in pig farms due to the conventional strengthening of barn facility standards and farmhouse compliance for odor reduction, and livestock manure temporary storage facilities at the bottom of breeding facilities, which are pointed out as the main cause of odor. The Enforcement Decree and Enforcement Rules of the Livestock Act were amended within this year to strengthen compliance with the management of odor and compost decay generated during the slurry pit and livestock manure fueling process. Therefore, technology is being developed to strengthen real-time monitoring by installing odor collection equipment using information and communication technology (ICT) for farms concerned about livestock odor. The transaction feedback unit 40, which includes the same function as the regular management system function of the joint resource utilization facility in connection with the livestock manure electronic handover system, calculates the amount of greenhouse gas emission reduction according to the greenhouse gas emission according to the caloric measurement after the above project, As the carbon reduction result data is generated, it is possible to calculate the amount of greenhouse gas generated while burning livestock manure and predict the degree of odor generation according to the calculation of the amount of greenhouse gas. When the information data of the degree of odor generation predicted by this is fed back to the fuel information management unit 10, the fuel information management unit 10 can reduce the degree of odor generation and the information data of the degree of odor generation by the linked agricultural cooperative server. Alternatively, information data on a method for manufacturing a structure or a composition or structure capable of reducing the degree of generation of the odor are transmitted.

As an embodiment, the composition capable of reducing the degree of odor generation is an adsorption composition for reducing odor generated during combustion of waste, and includes chloride, gluconate, organic acid and additives, wherein the organic acid is a humic substance, and the humic The anionic functional group of the material forms a chelate with the chloride and gluconate, and the additive is a three-dimensional porous structure prepared by heating a dry powder mixture including an organic binder and inorganic particles. In more detail, the humic material includes humin, humic acid (HA), and fulvic acid (FA), and is characterized in that it has a pH of 2 to 7.5, and the porous structure is A porous structure derived from Sargassum horneri is used. The composition capable of reducing the degree of odor generation is organic waste, especially agricultural by-products such as rice straw and barley straw, By adsorbing odorous substances including oil vapor generated during combustion of livestock manure, human manure, tree bark, industrial waste sludge, and food industrial waste, it is possible to efficiently reduce and prevent environmental pollution problems. In addition, the adsorbent composition for reducing odor according to the present invention can reduce production cost by using humic substances, which are waste resources, and can effectively adsorb odor substances by including a porous structure in which an organic binder and inorganic particles are fused.

Therefore, the present invention manages a series of processes of receiving biomass solid fuel based on the EPC O&M management system, calculating and receiving the received biomass solid fuel cost, and servicing (renting) biomass steam energy to customers. It is to provide a thermal energy and electricity supply management system using biomass livestock meal solid fuel. According to the thermal energy and electricity supply management system using biomass livestock solid fuel as described above, the following effects are obtained. Third, it is possible to monitor the electricity supply and demand status of electricity transaction and system marginal price (SMP) in real time, and at the same time, various operation information data such as biomass fuel cell power generation information and calorific value information can be monitored in real time. Fourth, when fuel is solidified, a high-speed fermenter method is adopted, and when livestock manure is put into the high-speed fermentor, carbon-reduction patented microorganisms are stirred together to reduce odor generation, thereby fundamentally solving the complaints of local residents. Fifth, since livestock manure is not treated as waste but recycled as fuel, the problem of total water quality in each region can be solved. Sixth, the number of breeding heads can be increased to respond to meat consumption, and the improvement of the total water quality system can induce companies to attract local industrial complexes. Seventh, at a time when LPG and LNG prices skyrocketed, it can help local manufacturing companies operating biomass livestock meal solid fuel industrial steam boilers improve their financial soundness and secure local government tax revenue.

Although the detailed description of the present invention described above has been described with reference to preferred embodiments of the present invention, those skilled in the art or those having ordinary knowledge in the art will find the spirit of the present invention described in the claims to be described later. And it will be understood that the present invention can be variously modified and changed without departing from the technical scope.

10: Fuel Information Management Department
10a: fuel data receiving unit
10b: Fuel transaction cost calculation transmission unit
10c: fuel data update unit
20: Energy Information Construction Department
20a: Energy DB unit
20b: Energy transaction DB department
30: transaction cost calculation unit
40: transaction feedback unit

Claims (15)

In the biomass energy transaction monitoring device,
A fuel information management unit that transmits and receives biomass fuel supply data in conjunction with the National Agricultural Cooperative Federation server;
An energy information construction unit that builds a biomass fuel conversion energy database;
a transaction cost calculation unit for calculating a biomass fuel conversion energy transaction cost according to the database built in the energy information establishment unit;
Based on the data built in the energy information construction unit and the transaction cost calculation unit,
A transaction feedback unit that calculates carbon reduction result data according to biomass energy and feeds back to the transaction cost calculation unit and the fuel information management unit;
The fuel information management unit,
A fuel data receiving unit that constructs a fuel supply database by receiving biomass fuel supply data in conjunction with a regional agricultural cooperative server;
a fuel transaction cost calculation transmission unit that calculates fuel transaction cost according to the biomass fuel supply amount data received by the fuel data receiving unit, constructs fuel transaction amount cost data, and transmits the data to the regional agricultural cooperative server;
A fuel data update unit for updating the fuel supply amount database and the fuel transaction amount cost data in real time according to the amount of change in biomass fuel supply data;
The fuel data update unit,
Inspection of biomass energy trade monitoring devices;
Update biomass fuel supply data check and biomass fuel validation test date data;
Biomass livestock solid fuel utilization thermal energy and electricity supply management system, characterized in that automatically updating the expiration date data of the biofuel test as the biofuel test start date data is updated. The method of claim 1, wherein the biomass energy transaction monitoring device,
A thermal energy and electricity supply management system using biomass livestock solid fuel, characterized by real-time monitoring of biomass fuel supply transaction data based on SCADA (Supervisory Control and Data Acquisition), an industrial control system. The method of claim 1, wherein the biomass energy transaction monitoring device,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized by real-time monitoring of measured values of steam pressure gauge, steam flowmeter, steam thermometer, feed water thermometer, watt-hour meter, and biomass meter. delete delete The method of claim 1, wherein the energy information building unit,
An energy DB unit for constructing a database by calculating the amount of energy converted to biomass fuel according to the amount of biomass fuel supplied;
The biomass fuel conversion energy is a biomass livestock solid fuel utilization thermal energy and electricity supply management system, characterized in that biomass steam energy. The method of claim 6, wherein the energy DB unit,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that for calculating the amount of biomass fuel conversion energy according to the biomass fuel supply amount by the following formula.

here, is the baseline heat release (tCO2/annum) of the biomass fuel boiler, is biomass fuel boiler heating energy (GJ/ton), Silver biomass fuel heating facility efficiency (%), is the biomass fuel boiler feedwater energy in GJ/ton. The method of claim 6, wherein the energy information building unit,
an energy account database including information related to biomass steam energy accounts based on the data collected in the energy DB unit; and
Biomass livestock solid fuel utilization thermal energy and electricity supply management system, characterized in that it further comprises; energy transaction DB unit for managing; The method of claim 8, wherein the energy customer database,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized by including the name, representative name, address, phone number and fax number of the biomass steam energy customer, e-mail address, transaction manager name and direct number or email address of the manager . The method of claim 8, wherein the transaction cost calculator,
Based on the data on the amount of energy sold by the biomass steam energy partner,
Biomass steam energy Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that the monthly biomass steam energy supply cost per customer is calculated. The method of claim 1, wherein the transaction feedback unit,
Based on the data built in the energy information construction unit and the transaction cost calculation unit,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that the carbon reduction result data is calculated by calculating the greenhouse gas emissions according to the calorimetric measurement after the project. The method of claim 11, wherein the greenhouse gas emissions according to calorimetric measurement after the project,
is the leakage emissions in year y of the biomass residue,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that the following equation is calculated.

here, y-year leakage emissions of silver biomass residues (tCO2/yr); is the CO2 emission factor of the most carbon-intensive fossil fuel used in the country (tCO2/GJ), is the amount of biomass used and included within the project boundary (tons); is the net calorific value (GJ/yr*Tons) of the biomass residue in category n in year y. The method of claim 11, wherein the transaction feedback unit,
According to the greenhouse gas emissions according to the calorimetric measurement after the above project,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that for calculating the amount of greenhouse gas emission reduction and feeding back the carbon reduction result data to the transaction cost calculation unit. The method of claim 13, wherein the transaction feedback unit,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that for calculating the amount of greenhouse gas emission reduction by the following formula.
;
;
here, is the project emissions from burning fossil fuels in process j in year y (tCO2/yr), is the amount of I fuel burned in process j in year y (Tons/yr), is the weighted average net calorific value of fuel i in year y (GJ/kg), is the weighted average CO2 emission factor of fuel i in year y (tCO2/GJ), is the CO2 emission factor of fuel i in year y (tCO2/kg). The method of claim 14, wherein the transaction feedback unit,
Thermal energy and electricity supply management system using biomass livestock solid fuel, characterized in that for feeding back to the fuel information management unit to control the amount of biomass fuel supply according to the amount of greenhouse gas emission reduction.