JP2004279073A - Method of calculating immobilized amount of carbon dioxide, apparatus for immobilizing carbon dioxide, and system for managing immobilized amount of carbon dioxide - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a carbon dioxide immobilizing apparatus for easily immobilizing carbon dioxide, a method of calculating the immobilized amount of carbon dioxide for calculating the immobilized amount of carbon dioxide, and a system for managing the immobilized amount of carbon dioxide for managing the calculated, immobilized amount of carbon dioxide. <P>SOLUTION: In the method of calculating the immobilized amount of carbon dioxide, a member 2a is subjected to carbonization treatment at a specific temperature, the weight of the member being subjected to carbonization treatment is measured, the resistance value of the member being subjected to carbonization treatment is measured, and the amount of carbon dioxide immobilized to the member being subjected to carbonization treatment is calculated, based on the measured weight of the member and the measured resistance. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is a carbon dioxide fixing device for carbonizing a member obtained by cutting down a tree, bamboo or the like and fixing the carbon dioxide, calculating the amount of carbon dioxide fixed to the member, a method thereof, and the fixed carbon dioxide. Related to a system for managing a fixed amount.
[0002]
[Prior art]
Carbon dioxide is one of the causes of global warming, and it is essential to reduce the amount of carbon dioxide released into the atmosphere. As one of the measures, it is conceivable to fix carbon dioxide by some method.
[0003]
Various methods have been considered and studied as a method for fixing carbon dioxide, but no method is known about fixing carbon dioxide using wood, bamboo, or the like.
[0004]
[Problems to be solved by the invention]
In addition, carbon dioxide can be easily fixed to a member or the like, a member or the like to which carbon dioxide is fixed can be used, and if the fixed amount of carbon dioxide in the member or the like can be calculated, the fixed amount of carbon dioxide can be individually and specifically specified. This is convenient because, for example, it becomes easier to respond to the target of carbon dioxide reduction by the national government or local governments, for example.
[0005]
In particular, the bamboo nodes are becoming narrowly used and becoming industrial waste, and the use of them is being sought.
[0006]
The problem to be solved by the present invention includes the above-mentioned problem as an example.
[0007]
Therefore, the present invention is an apparatus for fixing carbon dioxide for easily fixing carbon dioxide, a method for calculating a fixed amount of carbon dioxide for calculating the fixed amount of carbon dioxide, and for managing the calculated fixed amount of carbon dioxide. An object of the present invention is to provide a system for controlling the fixed amount of carbon dioxide.
[0008]
[Means for Solving the Problems]
Hereinafter, the present invention will be described. In addition, in order to facilitate understanding of the present invention, reference numerals in the accompanying drawings are added in parentheses, but the present invention is not limited to the illustrated embodiment.
[0009]
In the method for calculating the fixed amount of carbon dioxide according to the present invention, a member (2a) such as bamboo or wood is carbonized at a predetermined temperature, the weight of the carbonized member is measured, and the carbonized member is measured. The resistance value is measured, and the amount of carbon dioxide fixed to the carbonized member is calculated based on the measured weight of the member and the measured resistance value.
[0010]
According to this method, the fixed amount of carbon dioxide can be calculated.
[0011]
Further, the carbon dioxide immobilizing device (6) of the present invention has a carbonizing section for carbonizing members, and a control means () for controlling at least the temperature in the carbonizing section to a predetermined temperature. 6e), a cooling body supply means (6c) for shutting off air and cooling the carbonized member, and a cooling body discharging means (6d) for discharging the cooling body. It is characterized by having.
[0012]
With this configuration, the carbon dioxide can be easily fixed, and the member on which the carbon dioxide has been fixed can be efficiently cooled and quickly produced.
[0013]
Further, the carbon dioxide fixing device of the present invention includes a carbonizing unit for carbonizing the member, a weight measuring unit (7b) for measuring the weight of the member carbonized by the carbonizing unit, and the carbonized unit. Measuring means (7c) for measuring the resistance value of the member, and calculating means (7d) for calculating the carbon dioxide fixed amount in the carbonized member based on the measured weight of the member and the measured resistance value. , Is provided.
[0014]
In this way, the fixed amount of carbon dioxide fixed to the member to be carbonized can be calculated from the weight of the member. It is also possible to know the required weight of the member according to the required fixed amount of carbon dioxide.
[0015]
The fixed carbon dioxide amount management system (10) according to the present invention includes an image pickup means (3) for picking up bamboo, trees, and the like generated in a predetermined area (2), and an image pickup means for picking up images. Analyzing means (7a) for analyzing the amount of members that can be cut off based on the captured image, carbonizing means (6) for carbonizing the member at a predetermined temperature, and a predetermined carbonized at least analyzed by the analyzing means. Area information (10), weight information (11) of members cut from bamboo, trees and the like generated in the predetermined area, and a member calculated from the weight of the member when the member is carbonized. A database (9) including fixed amount information (12) of carbon dioxide to be fixed is provided.
[0016]
In this way, it is possible to control the amount of carbon dioxide fixed by carbonizing bamboo, trees, and the like in the predetermined area. In addition, the maximum fixed amount of carbon dioxide fixed to the member by the carbonization process in the current situation can be known almost in real time.
[0017]
A weight measuring unit for measuring a weight of the member carbonized by the carbonizing unit; a measuring unit for measuring a resistance value of the carbonized member; and a weight and measurement of the measured member. Calculating means for calculating the amount of carbon dioxide fixed to the carbonized member based on the resistance value thus obtained.
[0018]
In this way, the fixed amount of carbon dioxide fixed to the member to be carbonized can be calculated from the weight of the member. It is also possible to know the required weight of the member according to the required fixed amount of carbon dioxide.
[0019]
Also, at least one of the fixed amount information of carbon dioxide (16) calculated by the calculation means, the usage ratio information of members in the area (17), and the provided company information (18) is included. And a database (9a).
[0020]
In this way, a fixed amount of carbon dioxide obtained by carbonizing members such as trees and bamboos cut from a predetermined area, a predicted amount of carbon dioxide that can be fixed, and an actual amount of carbon dioxide from past to present. Can manage a fixed amount or the like.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a method for immobilizing carbon dioxide, a system for managing a fixed amount of carbon dioxide, and a carbonization apparatus according to the present invention will be described with reference to FIGS.
[0022]
FIG. 1 is a configuration diagram of a system for managing a fixed amount of carbon dioxide of the present invention, FIG. 2 shows a database, FIG. 2 (a) is an example thereof, and FIG. 2 (b) is another example.
[0023]
As shown in the figure, a fixed carbon dioxide amount management system 1 of the present invention includes an image pickup device 3 for picking up a bamboo, a tree, or the like 2 a generated in a predetermined area 2, and an image pickup device 3 and a communication line 4. And a member 2a, which is electrically connected to the management terminal 5 and is formed by cutting bamboo, trees, etc., in the predetermined area 2, is carbonized at a predetermined temperature based on the use and the like. And a carbonization treatment device 6 for performing the treatment. The member 2a is cut from a bamboo, a tree, or the like generated in the predetermined area 2 to a predetermined size. Further, the member 2a is particularly preferably a knot portion of bamboo. This is because the knot portion of the bamboo is hard and its shape does not easily collapse even after carbonization.
[0024]
As the image pickup device 3, for example, a digital video camera or the like is used. In addition, at least one image capturing device 3 is required to capture the predetermined area 2 from multiple directions. In addition, the image capturing device 3 transmits video information that is captured continuously or at predetermined time intervals and is captured to the management terminal 5 via the communication line 4.
[0025]
The management terminal 5 analyzes the image based on the video information transmitted from the image capturing device 3 and calculates the weight of the bamboo, tree, or the like (the member 2a when cut down) generated in the area 2. In addition, the management terminal 5 is configured to control the weight of the member 2a cut from the bamboo, tree, or the like generated in the predetermined area 2, the amount of carbon dioxide fixed by carbonizing the member 2a cut in the predetermined area 2, and the like. Manage. Further, the weight of the member 2a and the value of the amount of carbon dioxide fixed to the member 2a are updated every time transmission from the image pickup device 3 is performed.
[0026]
Specifically, the management terminal 5 includes at least a control unit 7 and a storage unit 8. The control unit 7 includes an analysis processing unit 7a, a weight measurement unit 7b, a measurement unit 7c, and a calculation unit 7d. Further, the control section 7 performs each processing by a program or the like corresponding to the processing of each section 7a to 7d. In addition, each process includes, for example, an image analysis process based on a video imaged by the image capturing device 3, and a tree, bamboo, or the like (member 2 a) having a certain weight within the predetermined area 2 from the image analysis process. Based on the analysis of whether the bamboo, trees, etc. (members 2a) are generated in the predetermined area 2, the members 2a obtained by cutting the bamboos, trees, etc. are carbonized by the carbonization processing device 6. It is obtained by control of the carbonization device 6 for producing the member 2a to which carbon is fixed, calculation of the fixed amount of carbon dioxide obtained by carbonizing a predetermined amount of the member 2a, analysis and calculation, and the like. This is a process of storing information such as weight in the database 8b. In addition, a calculation process of the weight of the member 2a such as a bamboo, a tree, or the like to be supplied to the carbonization device 6 from the required carbon dioxide fixed amount is also included.
[0027]
The analysis processing unit 7a has at least an image analysis unit and a calculation unit, analyzes the image based on the video information transmitted from the image capturing device 3, and generates a bamboo, a tree, or the like (in the case of being cut down) generated in the area 2. Calculates the weight of the member 2a).
[0028]
The weight measuring unit 7b measures the weight of the member to be carbonized by the carbonization device 6.
[0029]
The measuring unit 7c measures the resistance value of the member to be carbonized by the carbonization device 6.
[0030]
The calculating unit 7d calculates the amount of carbon dioxide fixed to the member to be carbonized based on the weight of the member 2a measured by the weight measuring unit 7b and the resistance value measured by the measuring unit 7c, and calculates the amount by the analyzing unit. A predicted value of the amount of carbon dioxide fixed to the member 2a by the carbonization process is calculated based on the weight of the member 2a. The calculating unit 7d can also calculate the weight of the member 2a necessary to obtain a member to which a predetermined amount of carbon dioxide is fixed.
[0031]
The storage unit 8 stores various programs 8a, databases 9, 9a, and the like. As shown in FIG. 2A, the database 9 includes at least one predetermined area information 10 calculated by the analysis processing unit 7a and weight information 11 of bamboo, trees, etc. (member 2a) generated in the area 2. Predicted value information 12 of the fixed amount of carbon dioxide fixed to the member 2a to be carbonized, calculated by the calculating unit 7d based on the weight information of the bamboo, tree, etc. (member 2a) obtained by the analysis processing unit 7a; , Is provided. When there are a plurality of predetermined regions 2 as shown in the figure, the weight information 11, the predicted value information 12, and the bamboo in the entire region (not shown) are provided for each of the regions 2 (A region 10a, B region 10b, etc.). It is preferable to include weight information and prediction value information of a tree or the like.
[0032]
As shown in FIG. 2B, the other database 9a includes weight information 13 of the member 2a actually cut from the predetermined area 2 and analyzed by the analysis processing unit 7a, and a weight of the member 2a carbonized. Information 14, resistance value information 15 of carbonized member 2a, fixed amount information 16 of carbon dioxide fixed to carbonized member calculated based on resistance value information 15, bamboo, tree, etc. in region 2 May be provided with use ratio information 17 of the member 2a obtained by cutting down, and information 18 of a company that provided the carbonized member by selling or the like. The company information 18 is the name of the company that sold the product, information on the intended use, and the like. In this way, it is possible to manage the fixed amount of carbon dioxide obtained by carbonizing a member such as a tree or bamboo cut from a predetermined area. In addition, by managing information (use, etc.) of the company after providing (selling) the carbonized member, the fixed amount of carbon dioxide can be reliably counted.
[0033]
FIG. 3 is a block process diagram of the carbonization processing, and FIG. 4 is a structural view of the carbonization processing chamber.
[0034]
Although not shown, the carbonization apparatus 6 includes at least a carbonization chamber and a heating unit for indirectly heating the carbonization chamber. Further, as shown in the drawing, the carbonization apparatus 6 has a member charging step 21, a residual heat / ignition step 22, a temperature increasing step 23, an air shutoff step 24, a cooling step 25, and a member discharging step 26. In order to control the temperature to a predetermined temperature in the temperature raising step 23, a temperature control step 27 is provided, and the temperature is controlled to the predetermined temperature. In the temperature raising step 23, the temperature is preferably raised to about 1000 ° C. in order to approximate the member 2a to pure carbon in order to easily measure the amount of carbon.
[0035]
In order to shut off the air in the air cutoff step 24 and the cooling step 25 to carbonize the member and quickly cool it, a cooling body supply step 28 for supplying a cooling body so as to cover the member to be carbonized, and a cooling body And a cooling body discharging step 29 for discharging. As the cooling body, for example, high-temperature sand is used. The reason for the high temperature is that if the carbonized member is rapidly cooled, cracks or the like occur. As shown in FIG. 4, the supply and discharge of the cooling body are, for example, as shown in FIG. 4, a shelf 6b for supporting the members 2a, 2a,. In the carbonization chamber 6a provided with a hopper 6c for supplying the water, and an opening / closing valve 6d for discharging the cooling body 35 supplied by the hopper 6c at the lowermost part, as a preheating / ignition step and a temperature raising step, After the heating temperature to the carbonization processing chamber 6a is controlled by the control unit 6e and the member 2a is carbonized, as an air cut-off step 24, the hopper 6c serving as a cooling body supply unit in the carbonization processing chamber is used as a cooling body 35. High-temperature sand is supplied to cover the carbonized member, and the air in the carbonization chamber is shut off and left. Thereby, since the air is shut off, it is possible to prevent the member 2a from burning. Further, the carbonized member can be efficiently cooled. Further, for example, the high-temperature sand is preferably used as the cooling body 35, but the cooling body 35 is not limited to the high-temperature sand. After a lapse of a predetermined time, the control unit 6e opens the on-off valve 6d as a cooling body discharging means, and discharges the cooling body 35 supplied into the carbonization chamber. The discharged cooling body 35 is returned to the hopper 6c again, and is again supplied from the hopper 6c into the carbonization chamber.
[0036]
As described above, the carbonization apparatus 6 puts the member 2a into the carbonization chamber and heats the inside of the carbonization chamber to a predetermined temperature, and then usually sets the air in the carbonization chamber so that the carbonized member does not burn. Is cut off and left to cool for a predetermined time. However, the carbonization apparatus 6 of the present embodiment includes a cooling body supply step 28 in order to perform cooling efficiently. Therefore, while the air is shut off by the supplied cooling body, it is possible to efficiently cool the carbonized member.
[0037]
The carbonized member is weighed by the weight measuring unit 7b of the management terminal 5, and the measuring unit 7c measures the resistance value of the carbonized member. This indicates that if the resistance value is 0Ω, the carbon dioxide content is 100%. According to the experiment, when the resistance value of the carbonized member is 0Ω, the carbonized member contains about 300 kg of carbon dioxide for 1 ton of the member made of bamboo before the carbonization process. I have. Based on the information on the resistance value and the weight, the fixed amount of carbon dioxide contained in the carbonized member is calculated. Further, the amount of carbon dioxide fixed on the carbonized member can be counted. In addition, the system manages the amount of the member 2a obtained by cutting bamboo, trees, and the like generated in the predetermined region 2, and carbonizes the member 2a by the carbonization device 6 based on the amount of the member 2a. The amount of carbon dioxide obtained by fixing carbon dioxide to 2a can be controlled. Further, in a predetermined area, the fixed amount of carbon dioxide obtained by carbonizing bamboo, trees, and the like in the area can be easily known. In addition, since information on bamboos, trees, and the like in a predetermined area is sequentially updated, even if bamboos, trees, and the like are reduced due to logging or the like, members made of bamboos, trees, or the like in the area are carbonized in real time. The amount of carbon dioxide obtained can be controlled.
[0038]
As described above, in the method for calculating the fixed amount of carbon dioxide of the present invention, the member 2a such as bamboo or wood is carbonized at a predetermined temperature, and the weight of the carbonized member is measured. The resistance value of the treated member is measured, and the amount of carbon dioxide fixed on the carbonized member is calculated based on the measured weight of the member and the measured resistance value. According to this method, the fixed amount of carbon dioxide can be calculated.
[0039]
Further, the carbonization device 6 as the carbon dioxide fixing device of the present invention has a carbonization chamber for carbonizing the member 2a and controls at least the temperature in the carbonization chamber to a predetermined temperature. Control unit 6e, a hopper 6c as a cooling body supply means for shutting off air to the carbonized member and supplying a cooling body for cooling, and an opening / closing valve for discharging the cooling body 6d. By doing so, it is possible to easily fix carbon dioxide and quickly produce a member having carbon dioxide fixed.
[0040]
In addition, the carbonization apparatus 6 as a carbon dioxide fixing apparatus of the present invention includes a carbonization chamber as carbonization means for carbonizing the member 2a, and a weight for measuring the weight of the member carbonized by the carbonization means. A weight measuring unit 7b as a measuring unit, a measuring unit 7c as a measuring unit for measuring a resistance value of the carbonized member, a member carbonized based on the measured weight of the member and the measured resistance value And a calculating unit 7d as calculating means for calculating the fixed amount of carbon dioxide. In this way, the member can be manufactured according to the required amount of carbon dioxide. Further, the amount of carbon dioxide immobilized on the manufactured member can be calculated.
[0041]
Further, the system for managing the fixed amount of carbon dioxide of the present invention includes an image pickup device 3 as an image pickup unit for picking up bamboos, trees, and the like generated in the predetermined area 2, and a video image picked up by the image pickup unit. An analysis processing unit 7a as an analysis means for analyzing the amount of the member 2a that can be cut based on the carbonization processing chamber as a carbonization means for carbonizing the member 2a at a predetermined temperature, and analysis at least by the analysis means When the carbonization process is performed on the specified area information 10 obtained, the weight information 11 of the member 2a cut from bamboo, trees, and the like generated in the predetermined area 2, and the member 2a calculated from the weight of the member 2a And a database 9 including fixed amount information 12 of carbon dioxide fixed to the member. In this way, it is possible to control the amount of carbon dioxide fixed by carbonizing bamboo, trees, and the like in the predetermined area.
[0042]
A weight measuring unit 7b as a weight measuring unit for measuring the weight of the carbonized member by the carbonizing unit; a measuring unit 7c as a measuring unit for measuring the resistance value of the carbonized member; A calculating unit 7d may be provided as a calculating unit that calculates the amount of carbon dioxide fixed to the carbonized member based on the measured weight of the member and the measured resistance value. In this way, the member can be manufactured according to the required amount of carbon dioxide. Further, the amount of carbon dioxide immobilized on the manufactured member can be calculated.
[0043]
Further, at least the fixed amount information 16 of carbon dioxide calculated by the calculating unit 7d, the use ratio information 17 of the member 2a in the region 2, information 18 of a company to which the member to be carbonized is provided (sold), And a database 9a including any one of the above. In this way, a fixed amount of carbon dioxide obtained by carbonizing members such as trees and bamboos cut from a predetermined area, an amount capable of fixing carbon dioxide, an amount of carbon dioxide actually fixed, and the like. Can be managed.
[0044]
The use of bamboo nodes as the member 2a is useful for treating industrial waste.
[0045]
The carbon dioxide fixing device and the carbon dioxide fixed amount management system of the present invention are not limited to the present embodiment, and may be implemented in other embodiments. For example, the number of combustion chambers is not limited to one, and a plurality of combustion chambers may be provided. The carbonization device and the management terminal may be integrated. Further, the analysis unit may be provided in the image pickup device.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a carbon dioxide fixed amount management system of the present invention.
FIG. 2 is an example of a database.
FIG. 3 is a block diagram of a carbonization process.
FIG. 4 is a structural diagram of a carbonization chamber.
[Explanation of symbols]
2 area 2a member 3 image capturing means (image capturing device)
6 Carbon dioxide immobilization device (carbonization device)
6c Cooling body supply means (hopper)
6d Cooling body discharge means (open / close valve)
6e Heating means (Ignition / heating control unit)
7a Analysis means (analysis unit)
7b Weight measuring means (weight measuring unit)
7c Measuring means (measuring unit)
7d calculation means (calculation unit)
8b, 8c Database 10 Fixed Carbon Dioxide Management System

Claims (6)

The member is carbonized at a predetermined temperature, and the weight of the carbonized member is measured, and the resistance value of the carbonized member is measured. Based on the measured weight of the member and the measured resistance value, A method for calculating the amount of carbon dioxide fixed, which calculates the amount of carbon dioxide fixed to a member that has been carbonized. A carbonization section for carbonizing the member, and control means for controlling at least the temperature in the carbonization section to a predetermined temperature; and blocking and cooling air to the carbonized member And a cooling body discharging means for discharging the cooling body. Carbonization means for carbonizing the member;
Weight measuring means for measuring the weight of the member carbonized by the carbonizing means,
Measuring means for measuring the resistance value of the carbonized member,
Calculation means for calculating the carbon dioxide fixed amount in the carbonized member based on the measured weight of the member and the measured resistance value,
An apparatus for immobilizing carbon dioxide, comprising: Image capturing means for capturing a bamboo, a tree, or the like generated in a predetermined area,
Analysis means for analyzing the amount of members that can be cut based on the video imaged by the image imaging means,
Carbonization means for carbonizing the member at a predetermined temperature,
When at least the predetermined area information analyzed by the analysis means, the weight information of the members cut from bamboo, trees, and the like generated in the predetermined area, and the carbonization processing of the member calculated from the weight of the member And a fixed amount information of carbon dioxide fixed to the member in the database,
A fixed amount management system for carbon dioxide, comprising: Weight measuring means for measuring the weight of the member carbonized by the carbonizing means,
Measuring means for measuring the resistance value of the carbonized member,
Calculation means for calculating the amount of carbon dioxide fixed to the carbonized member based on the measured weight of the member and the measured resistance value,
The fixed amount management system of carbon dioxide according to claim 4, comprising: A database including at least one of the fixed amount information of carbon dioxide calculated by the calculation unit, the usage ratio information of the member in the region, and the information of the company to which the member to be carbonized is provided. The fixed amount management system for carbon dioxide according to claim 5.

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