JP2002109157A - Method and device for evaluating product environmental load - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an environment evaluating method and an environment evaluating device capable of quickly and easily inputting product material information in a raw material procurement step in the case of evaluating product environmental load. SOLUTION: This device calculates the abandoned source unit of an environmental load factor in relation to material introduced in a raw material procurement step, preliminarily stores the abandoned source unit while making the abandoned source unit correspond to material identification information defined by an inter-industry relations table, calculates the product environmental load in the raw material procurement step by multiplying the abandoned source unit of each stored material by the quantity consumed of product material introduced, and converts standard material identification information into the material identification information defined by the inter-industry relations table and subsequently calculates the product environmental load in the case the material introduced in the raw material procurement step is represented by the standard material identification information in the raw material procurement step.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an environmental load evaluation method and apparatus which can easily evaluate the environmental load of a product.

[0002]

2. Description of the Related Art In recent years, with the social rise to global environmental problems, it has been required not only to consider the environment exerted by production activities in factories, but also to reduce the environmental load of products themselves. Therefore, the life cycle assessment (L
CA) is drawing attention. LCA is a method for analyzing and evaluating the load that a product exerts on the environment throughout its life and improving it to reduce the environmental load. That is, LCA
Is to grasp and evaluate the environmental load through the product life cycle (raw material collection → production → distribution → use → disposal / recycling, etc.). LCA is not a partial good or bad, it is a comprehensive assessment of the product life, and it is a means to quantitatively grasp the load such as air pollution, resource efficiency and waste volume, and to make scientific or rational improvements. The feature is that it can be used.

In order to determine LCA, it is necessary to first pick up all the materials used in a product, and to accumulate the environmental load until the material is produced (accumulation method). Yes, analysis is generally performed using an "input-output table" (the Input-Output Law).

[0004] The "input-output table" is statistical data issued by the Internal Affairs and Communications Agency every five years, and is a matrix table showing the relationship between the transfer of money (demand and supply) between the industrial sectors in one country. is there. Using this input-output table, for example, to make 1 g of steel, “US $「 ”,“ Machine ○ ¥ ”,“ Oil ×
The supply amount such as "yen" can be calculated backward. The calculation results cover the domestic ripple effect, and as a result, it goes back as far as possible to the source of the material. Industrial sector 1 from here
Fossil fuels (coal, oil, gas, etc.) input to calculate the unit can be estimated, and CO ₂ and NO of these fossil fuels can be estimated.
By multiplying x, SOx emission factor, etc., the emission unit in the industrial sector can be obtained. Here, the emission unit refers to the amount of emission of a factor (CO ₂ , SOx, NOx, etc.) that affects the environmental load per unit of input material. That is, [g] for metal and plastic, [m] for paper
2], in the case of electric power, it is defined as the emission amount of environmental load factor per [kwh].

[0005] In principle, the emission amount can be calculated by multiplying this emission unit and the amount of the input material (used amount). Therefore, if this emission basic unit is obtained in advance for each of various materials, it can be used as a conversion coefficient for converting the amount of use of each material into the amount of emission [g] of CO2 or the like.

The emission unit used is determined as follows. That is, from the input-output table, for each material, six fossil fuels (coal, crude oil, natural gas, petroleum products, coal products, city gas, etc.), which are sources of environmental load factors ((CO ₂ , SOx, NOx, etc.)) Next, the inverse matrix of the input-output table for the six fossil fuels is calculated for the six types of fossil fuels, and the CO2 emissions from the six types are calculated.
The sum of the quantities of The amount of the CO ₂ becomes its material 1 per unit CO ₂ emission intensity.

As described above, since the emission intensity can be easily obtained from the input-output table, the input-output method is generally used to perform LCA. It is necessary to apply to the most appropriate item of.

[0008]

SUMMARY OF THE INVENTION It is important to evaluate the environmental impact of a product over the entire life cycle of the product, from the manufacturing stage of the product to the end of its life and the stage of disposal or recycling. Has been
Although the evaluation method has been studied, there has been a problem that the evaluation of the environmental load by the conventional method requires a great deal of time and labor for the evaluation.

[0009] In particular, home appliances and the like are manufactured in a huge quantity and variety, and have a large proportion of the environmental load.
Evaluation by CA is important, and it is necessary to dig into the issues such as what stage and what environmental impact the product life cycle has, and at what stage what should be improved to reduce the environmental impact. A system that needs to be reflected in improvements, but can be used more quickly and easily for products that have a short development period, such as home appliances, so that they can be used to perform life cycle evaluation from the design stage. The development of is expected.

The LCA is generally divided into the stages of raw material procurement → production → distribution → use → disposal / recycling (see FIG. 1), and each item must be input by an operator. Time is required in the raw material procurement stage. For example, if you take one air conditioner,
The number of parts is close to 100, and the operator has to input the material, weight, size, etc. of each part. When this becomes a personal computer, several hundred more parts must be investigated. Also, not all parts are manufactured by PC manufacturers, most parts are made by another subcontractor, and not all designers are experts in materials, so it takes a lot of time and time to research materials. It takes effort. Moreover, even if you know the material, finding which entry in the input-output table it applies to is not an easy task.

[0011] The input-output table categorizes materials into over 3000 items, which are also classified into the unique input-output table classifications and expressions. Great effort is required to find the code number. Moreover, SUS405-WR of metal products
For products that are generally treated with JIS symbols, such as (JIS name: stainless steel wire), from the name of the product, "large classification: 262016 special steel hot rolled steel"-"middle classification: 26210163 special" Steel Special Purpose Steel "
-It is very difficult to find "small classification: 2621016303 stainless steel (chromium)".

[0012] The metal material and non-ferrous metal material of product parts are often represented by JIS symbols, and it takes a very long time for the analysis operator to find the name of the input-output table therefrom. .

The same applies to the case of plastic,
Resin called DF (vinylidene fluoride resin)
2041099 Other synthetic resins "-" Minor classification: 204
Searching for "1099402 fluororesin" also places a heavy burden on the analysis operator.

As described above, conventionally, when evaluating the environmental impact of a product by LCA, it takes a great deal of time to select a material code or a material name defined in an input-output table. There has been a problem that an operation for inputting product-specific information such as a material and an amount of the product at the stage cannot be performed quickly.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide an environmental load evaluation method and an environmental load evaluation apparatus which can quickly and easily input material information of a product in a raw material procurement stage. And

[0016]

SUMMARY OF THE INVENTION The method and apparatus for evaluating environmental load according to the present invention provide a method for procuring raw materials,
It is divided into production, distribution, use, disposal, and recycling stages, and the emission unit of the environmental load factor generated in each stage is provided in advance, and the product is multiplied by the amount of use or input for each product, thereby Calculating the environmental load at least in the raw material procurement stage, calculating the emission intensity of the environmental load factor relating to the input material at that stage from the input-output table, and defining it in the input-output table. The material identification information (material code and name in the input-output table) stored in advance and stored in advance, and the stored emission unit for each material is multiplied by the amount of input material used in the product to procure the raw material. When the environmental load of the product at the stage is determined, and the input material is represented by standard material identification information (for example, JIS symbol, JIS name) After converting the material identification information of the standard into the material identification information defined in the input-output table, by obtaining the environmental load of the product, at the time of material input work of the product, it is familiar to the worker. Since the input can be performed in the form of a certain JIS symbol or abbreviation, the input operation of the information of the material of the product in the raw material procurement stage can be performed quickly and easily, and the operator can easily use the LCA analysis.

Preferably, the material identification information of the standard defined by applying the material identification information of the standard to the classification of the material identification information defined in the input-output table and the material identification information defined in the input-output table are prepared. A correspondence table (a conversion table in the description of the embodiment) with the material identification information is stored in advance, and using this correspondence table,
The material identification information of the standard is converted into the material identification information defined in the input-output table.

[0018]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of an environmental load evaluation apparatus according to the present invention.

(Outline of Environmental Load Evaluating Apparatus) FIG. 1 schematically shows a processing procedure of the environmental load evaluating apparatus according to the present embodiment.

In this apparatus, the life cycle of a product is divided into stages indicated by S1 to S6 in FIG. 1, and the load on the environment exerted by the product is evaluated for each stage, and the results of each stage are integrated. This is to evaluate the environmental impact of this product throughout its life cycle.

That is, in this apparatus, the life cycle of a product is defined by life stages S1 and
Life stage S2 at the stage of manufacturing, life stage S3 at the stage of distribution, life stage S4 at the stage of use by the user, life stage S5 at the end of product life and disposal stage, and recycling stage of discarded products And the life stage S6. Here, the reason for considering the recycling stage is that the recycled material is procured again as a raw material in the raw material procurement stage S1.

Each life stage is analyzed from the viewpoint of environmental load, modeling is performed based on the analysis result, and an environmental load calculation formula as a standard model for obtaining a load on the environment at each stage of the product is obtained. Te Then, in each stage, individual values determined for each component, material, etc. of the product are substituted into the above-mentioned environmental load calculation formula so as to obtain the environmental load of a desired product. The individual values determined for each component and each material of the product are based on emission unit values obtained from an input-output table which is highly reliable statistical data. If the environmental load at each stage is determined, the environmental load of the entire product life cycle can be evaluated based on the total emission of environmental load factors at each life stage.

Here, the emission unit is a factor (CO ₂ , SO ₂₎ affecting the environment per unit of input material.
x. NOx). That is, it is defined as the emission amount of environmental load factor per [g] for metal and plastic, [m ² ] for paper, and [kWh] for electric power. In principle, the emission amount can be calculated by multiplying this emission unit and the input material amount (used amount). Therefore, if this emission basic unit is previously determined and obtained for each of various materials, a conversion coefficient that can convert the amount of use ([g], etc.) of each material into the amount of CO ₂ (SOx.NOx) emission [g] can be obtained. Can be used.

The details will be described below.

FIG. 1 shows the life stages S1 to S6 and data items to be assigned to a format (environmental load calculation formula) provided for use in calculating the environmental load for each stage. By applying the used material or the discharged material indicated in each data item to the environmental load calculation formula together with the emission basic unit, CO2 as an environmental load factor is obtained.
₂ Calculate emissions of carbon dioxide, SO _x (sulfur oxide), and NO _x (nitrogen oxide).

Hereinafter, each stage, ie, [1] raw material procurement stage (S1), [2] production stage (S2), [3] distribution stage (S3), [4] use stage (S4), [5] Disposal stage (S
5), [6] The concept and calculation method will be described step by step for each recycling stage (S6).

In this apparatus, processes (for example, truck transportation in the distribution stage, input energy in the disposal stage, etc.) that are uniquely determined are modeled (uniform, general-purpose), and various materials that cannot be determined, Parts and input energy do not go back to the source stream, but instead seek to determine the amount of environmental load factor emissions using emission intensity determined from reliable data.

As the reliable data, for example,
Use the data in the Input-Output Table. Since the input-output table covers all the ripple effects of domestic supply and demand, the result is the same as going back to the headwaters.

[0029] The "input-output table" means that
This is statistical data issued every year, and is a matrix table showing the relationship between supply and demand (demand and supply) between industrial sectors in one country. Using this input-output table, for example, to make 1 g of steel, supply amounts such as "rice in US", "JPY in machinery", "JPY in transport", "JPY in oil", and "JPY in electricity" Can be calculated back. The calculation results cover the domestic ripple effect, and as a result, the source of the material goes back as far as possible.

Therefore, the back calculation of the CO ₂ emission can cover the origin of CO ₂ (molecular weight is 44) by obtaining how much fossil fuel is supplied to produce a material (iron if iron). . That is, six fuel types (coal, crude oil,
The amount of natural gas, petroleum products, coal products, city gas) used is calculated and multiplied by each carbon content. Assuming that all the carbon (molecular weight is 12) has been used for combustion, CO ₂ (44 / mol.
12) can be calculated.

[1] Raw Material Procurement Stage (S1) FIG. 4 shows a format of an example of an environmental load calculation formula in the raw material procurement stage.

In this format, the material classification is described in the row direction, and the names of the component parts of the product (part name 1, part name 2,...) Are input in the column direction. In the blank space, the used amount of each material is input for each of the parts.

On the right of the component parts column, the amount of each material used is shown.
The total is displayed, and the emission intensity stored in the right column
By multiplying the environmental load factor for each material
(CO _Two, SOx, NOx).

Here, as the material classification items, ten or more items out of 187 classifications integrated by the input-output table are adopted.

The emission unit used for each material is determined in the following manner. That is, from the input-output table, the environmental load factors (CO ₂ , SO
x, NOx, etc.) 6 fossil fuels (coal, crude oil, natural gas, petroleum products, coal products, city gas)
Determine the amount of used. Next, an inverse matrix calculation of the input-output table of the input-output table was performed for these six fossil fuels, and
The total amount of CO ₂ (environmental load factor) environmental factors emitted by the species is determined. The amount of the CO ₂ becomes the emission intensity of CO ₂ per the material one unit.

Note that SO _x, N which are other environmental load factors
The O _x emission intensity can be determined using the CO ₂ emission intensity already determined. That is, the basic unit of SO _{x and} NO _{x for} each of the six fuel types is quoted from the statistical data, and the basic unit of CO ₂ emission for the six fuel types is SO _x / CO
_{2. The} sum of the product of NO _x / CO ₂ is SO _{x ,}
It is a unit _of emission of NOx.

[2] Manufacturing Stage (S2) FIG. 5 shows a calculation format in the manufacturing stage.
At the manufacturing stage, various types of energy such as electricity, gas, and water to be supplied to one product to be analyzed, and materials to be used such as auxiliary materials are input. When it is difficult to specify the amount of input per product to be analyzed, the actual problem is that the production energy and the production cost are almost in a proportional relationship. In contrast, the value obtained by dividing by the ratio of the shipment value of one product to be analyzed to the total shipment value is defined as the input amount per product.

The emission basic unit for production energy is
As in [1] (raw material procurement stage), it is calculated by inverse matrix calculation using an input-output table.

That is, the amounts of the six fossil fuels (coal, crude oil, natural gas, petroleum products, coal products, and city gas) used to generate each energy are determined from the input-output table. Next, an inverse matrix calculation of the input coefficient table of the input-output table is performed for these six types of fossil fuels, and the total amount of the environmental load factors (CO ₂ , SOx, NOx) emitted by the six types is calculated. The amount of this environmental factor is the emission intensity per unit of energy.

[3] Distribution Stage (S3) FIG. 6 shows a calculation format of the distribution stage. Emissions related to distribution are assumed to be derived from fuel (light oil) of transport trucks. For home appliances, from factory to sales bases nationwide 10
[T] Direct delivery by truck, 2 from the sales base to each retail store
[T] Transported by truck. Therefore, for the products for which the packing volume or the number of products to be analyzed is determined, the number of products to be loaded is input and distributed per one product to be analyzed.

The average transport distance from the factory to the sales base is obtained by multiplying the distance from each store to the distribution ratio of the base to all the bases and adding the total of all bases. In addition, the transportation distance from the base to the retail store is difficult to identify, so the average
[Km] and input.

The above calculated value is defined as the average transport distance of home electric appliances, and the CO ₂ per unit total distance [km] of the truck _,
The product of the SOx and NOx emission intensity is the emission amount at the distribution stage. Emission intensity shall be determined from statistical data.

[4] Usage Stage (S4) FIG. 7 shows a calculation format of the usage stage. For the input materials and energy, such as electricity, water, and paper, generated during the use stage of the product, the usage amount and frequency of use per product and the average life of the product are input, and the total usage amount in the life cycle is calculated.

The emission intensity is calculated by inverse matrix calculation using an input-output table as in [1].

[5] [6] Disposal and recycling stages (S
5, S6) FIG. 8 shows a calculation format at the disposal stage, and FIG. 9 shows a calculation format at the recycling stage. For example, if the product to be analyzed is a certain type of home appliance,
In the recycling process, a model flow is established from the disposal statistics of household electric appliances in cities designated by government ordinance. From the model flow based on the disposal statistics, it is possible to calculate the respective emissions related to the operational energy.

FIG. 3 shows a model flow of the disposal and recycling steps and calculation conditions in this embodiment.

First, discarded home electric appliances are collected by a collector and transported to an intermediate processing step. Emissions of environmental load factors at this stage are derived from fuel consumption and exhaust of the truck transportation means. In the intermediate treatment step, the product is disassembled and divided into recycled and non-recycled materials. Emission of environmental load factors in this process is due to the amount of energy required for processing.

[0048] Recycled materials include iron, copper, aluminum,
Consider paper, cardboard and glass.

These recycled materials are transported to a recycling facility by transport means. Also in this case, the emission of environmental load factors due to the transportation means is taken into consideration. In the recycling facility, the rate at which the recycled material is used again as a raw material of the product, that is, the reduction rate, is considered. The raw materials to be reused are expressed as minus because they contribute to reducing the environmental load factor in the raw material procurement step S1.

In the actual calculation, as shown in FIG. 9, as the input amount of each recycled material, the amount used in the raw material stage is used as it is. Then, this amount is multiplied by the recovery rate and the reduction rate to determine the amount reduced by recycling. Then, these are multiplied by the emission basic unit to obtain the amount of the environmental load factor expressed as a minus.

The respective recovery rates and energy reduction rates are based on the values obtained from the literature and the like as initial values. For example, if the recovery rate and the like are arbitrarily changed, a corresponding environmental load simulation can be performed.

The amount of the environmental load factor caused by the transportation means and the environmental load factor discharged when materials other than recycled materials are discarded are, of course, positive factors in accordance with the format shown in FIG. calculate.

The concept of the model which is the basis for calculating the environmental load in each step, that is, each life stage in the life cycle of the product has been described above. In this embodiment, the system is configured as shown in FIG. LC
A analysis processing is realized.

In FIG. 2, 21 is an input unit, 22 is a processing unit, 23 is an output unit, and 24 is an external storage device. The input unit 21 is for inputting necessary information, and the processing unit 22 has the environmental load calculation formula modeled for each stage described above. It has a function of calculating necessary elements using the emission intensity obtained by using. The processing unit 22
Are the individual components of the product to be evaluated, which are necessary for the calculation at each stage input by the operator using the input unit 21, the material of the component, the amount used, the production energy (electricity,
Water, gas, petroleum products, etc.), a function of holding individual element information for storing individual necessary information such as an incineration rate and a landfill rate in a disposal stage, and a function of graphing the calculated various information.

The processing unit 22 also includes various information such as an embedded input operation screen, an edit screen, and a menu screen, which are necessary items for supporting the operator to easily input information necessary for the environmental load calculation. It has a function of outputting a simple screen to the output unit 23 for display.

The output unit 23 displays various screens associated with the processing of the processing unit 22, and generally corresponds to a display. The output unit 23 may be a hard copy output device such as a printer in addition to the display, or may have a configuration including both. The external storage device 24 is a large-capacity storage device such as a hard disk or an optical disk for storing necessary information and processing results.

In the environmental load evaluation apparatus having such a configuration, when an instruction to start analysis is given from the input unit 21 to the processing unit 22,
The processing unit 22 first requests designation of what the product to be analyzed is. Therefore, the operator instructs a specific product name of the product to be analyzed from the input unit 21.

In response to this, the processing unit 22 selects necessary information related to the product of the product name from the input-output table according to the product name. Then, a screen for prompting input of data necessary for the arithmetic processing is displayed on the output unit 23 corresponding to each life stage. The operator inputs data necessary for analysis of the analysis target product from the input unit 21 according to the request.

For example, in the raw material procurement stage,
It is the material and the amount of the component parts per unit.

Other necessary information at each life stage,
For example, the consumption of six fuel types (coal, crude oil, natural gas, petroleum products, coal products, city gas) in the raw material procurement stage, and the production energy per unit (electricity, water) required in the production stage , Gas, petroleum products, etc.), the transport distance of the truck in the product transport process in the distribution stage, and the life of the product such as electricity, water, paper input in the use process if it is in the use stage The processing unit 22 automatically selects and extracts the total period total and the like from the input-output table.

Then, the required emission intensity is obtained from the above, and using these and various data input by the operator, the above-mentioned standard modeled arithmetic expression is used to calculate:
Calculate the environmental load at each stage and obtain the total environmental load over the entire life cycle. Necessary information including these calculation data is filed and stored in the external storage device 24.

The calculated data is output to the output unit 23 and presented. Further, when the operator instructs the graph display by operating the input unit 21, the processing unit 22 graphs the obtained data according to the instruction, and displays the result on the output unit 23.

In the environmental load evaluation device shown in FIG. 2, a process that is uniquely determined, that is, a rough mechanism of environmental load in each life stage in a life cycle is modeled, and this model is applied to any product. In other words, an arithmetic expression corresponding to a standard model for each life stage is prepared, and the environmental load is calculated according to the arithmetic expression corresponding to the model.

Next, an example of calculating the environmental load in the case of, for example, a color TV using the environmental load evaluating apparatus having the configuration shown in FIG. 2 will be specifically described. Here, the environmental load is CO
_{Although the} calculation of the emission amount of No. ₂ will be described, SOx and NOx can be similarly calculated.

[1] Material Procurement Stage In the material procurement stage, first, used parts and constituent materials are specified to specify them. In the case of color TV,
The component names include a housing, a PC board assembly, a chassis, a CRT, and the like.

As a result, 5.4 [kg] of steel was used for the entire product.
5.9 [kg] obtained by multiplying the CO ₂ emission intensity of steel obtained from the Input-Output Table: 1.09 [gCO ₂ / g] CO
₂ emissions. The total sum of these developments in each department is 13
7 kg, and the amount of CO ₂ emissions at the raw material procurement stage is calculated.

[2] Manufacturing Stage In the manufacturing stage, details are entered for each input energy. That is, the input energy per unit in the assembly factory is obtained. The total is 3.4 [kW], and 396 [g] obtained by multiplying 1.17 × 10 ² [gCO ₂ / kWh] obtained from the input-output table is the CO ₂ emission derived from the input power. In this way, the total of 450 [g] of each energy is the CO ₂ emission amount at the production stage.

[3] Distribution Stage In the distribution stage, 505 [km] obtained by weighted averaging in consideration of the distribution ratio is input as the transport distance from the factory to the distribution base. In the format, there is a column for entering the packing volume, and the number of loaded units per 10 [t] truck (80 [%])
(Assuming loading) can be obtained, but for products with a fixed loading number, the number is directly input. For this model,
The latter 56 units will be introduced.

[0069] Therefore the transport distance divided by stacking number, of 10 [t] track determined from literature values C0 ₂ emission intensity:
Multiply by 7.42 × 10 ² [gCO ₂ / km] and 5.3 kg
Is found. Next, 20 km on average from the base to the retail store
And the emission intensity of 2 [t] trucks is 3.23 × 10 ²
[GC0 ₂ / km] plus 0.02 [g] and obtained by multiplying the, 5.4 kg is CO ₂ emissions distribution stage.

[4] Usage Stage In the usage stage, 0.6 [kWh] is consumed per day in consideration of the power consumption of the color TV and the average usage time. Assuming an average life of 9 years, a life cycle of 1980 [kW]
h] of power. Therefore, 231 [kg] obtained by multiplying the emission basic unit 1.17 × 10 ² [g / kWh] obtained from the input-output table is the CO ₂ emission amount in the use stage.

[5] Discarding Stage In the discarding stage, there is no new input item since the calculation is performed using the data input in the above-mentioned “[1] Raw material procurement stage” as it is. The calculation method is obtained according to the flow of FIG. That is, the used home electric appliances are collected by a local government or the like, and the average distance of 20 [km] is 4 [t] trucks 60.
[%] To be transported to the intermediate treatment plant,
A total emission unit of 4.72 × 10 ^{2 was} added to 60 [kg] of the total weight.
And 235 [kg] of CO ₂ are discharged.

[0072] Then for CO ₂ of the power 6.5g and diesel 1.6g per weight kg in the middle treatment plant discharges, respectively 390 [g], the CO ₂ emissions 95 [g].

Next, iron, copper, aluminum, glass, paper, corrugated cardboard, etc. are separated at each collection rate, and the collected recycled materials (total 11 kg) are collected into a 20 [t] truck 60.
Under the loading of [%], the material is transported to the material recycling facility through an average distance of 40 [km].

That is, from the unit emission of 20 [t] trucks of 1,180 [gCO ₂ / km], 42 [g] of C
O ₂ evolves.

On the other hand, the debris 49 [k
g] is transported to the final disposal site by an average distance of 10 km with 10 [t] trucks loaded at 60%. Therefore 1
0 [t] Emission basic unit of truck: 7.42 × 10 ² , 6
1 [g] of CO ₂ is emitted.

At the final disposal site, 42.3 [%] of 21 [kg] was incinerated based on the household appliances treatment statistics of the city designated by government ordinance, and the emission intensity related to garbage collection was 1.08 × 1.
5. 0 ^-2 [gCO ₂ / g], emission intensity related to incineration
From 89 × 10 ^-2 [gCO ₂ / g], 223 g, 142
8 g of CO2 are emitted.

Further, as the direct emission of carbon by incineration, the emission unit consumption of incineration determined from the carbon content in plastic and paper is 3.14 [gCO _{2 /} g], 1.61 [gC
O ₂ / g], 13,266 [g], 2,113
[G] is calculated to emit CO ₂ .

From the statistical data, the residual after incineration was an average of 14.4 [%], resulting in a weight of 6.9 [kg], and 6.89 × 10 ^-2 [gCO ₂ / g] for the ash discharge. Under the unit,
This is a calculation that emits 34 g of CO ₂ .

Then, in addition to the incineration ash and the direct landfill treatment amount of 57.7 [%] based on the above statistical data, 3
5.1 kg is landfilled and 1.08 × 10 ^-2 g
CO ₂ / g] is emitted in a total of 380 [g].

As described above, at the disposal stage, a total of 18.2 [kg] of C including the load related to the work for recycling is included.
It is calculated that O ₂ is emitted.

[6] Recycling Stage In the recycling stage, for example, a steel collection rate of 97
[%], And re-entered in the middle of the material production process. Therefore, from the energy load for producing a material from 100% of virgin material, the ratio of the energy load reduced by introducing a recycled material is referred to as a reduction rate, and in the case of iron, 65% contributes to the load reduction. Will do.

That is, “the amount of iron input (5.6 [k
g]) x recovery rate (97.4 [%]) x reduction rate (65
[%]) = 3.5 [kg] ”is the load reduction amount. Therefore, the emission intensity 1.0 calculated from the iron-input-output table described above is used.
3.8 [kg] multiplied by 9 [gCO ₂ / g] is expressed as a minus amount with respect to the entire load as a CO ₂ load reduction.

As described above, the emission amount for each life stage is obtained from [1] to [6], and, for example, a graph as shown in FIG. 12 can be drawn as a composition ratio.

That is, FIG. 11 shows an embodiment of the calculation result in the color TV calculated as in the above calculation example.

As a result of inputting color TV data in accordance with FIGS. 4 to 9 described above, calculation results as shown in FIGS. 11A and 11B were obtained. In this system, for example, a graph as shown in FIG. 12 is obtained.

FIGS. 12 (a), 12 (b) and 12 (c) are pie charts showing the CO ₂ , SO _{x and} NO _x emission ratios _, respectively. The numerical values of the results shown in FIG. And displayed on the output unit 23. FIG. 12A shows C
This figure shows the O ₂ emission ratio, and it can be seen from this figure that the raw material procurement stage occupies 1/3 of the entire life cycle and the use stage occupies 60%. FIG. 12 (b) shows the SOx emission ratio, which shows that the distribution stage and the disposal stage occupy around 40% each. FIG. 12C shows the NOx emission ratio, which is characterized by occupying nearly half in the use stage. By graphing in this manner, the weight of the environmental load emission of each emission factor can be seen at a glance, and an improvement measure of load reduction can be taken to the next design stage.

Further, it is possible to quantitatively grasp the load reduction effect of recycling. In other words, the values of the recovery rate and reduction rate in the “[5] disposal stage” and “[6] recycling stage” were fixed as default values, but by changing these values, how much load can be reduced I understand.

For example, a color TV product weight of 60 [k]
g] is occupied by 51% of the cathode ray tube, and each emission amount is about 30%. Therefore, when the glass recycling rate (recovery rate) is changed to 50 [%] and 100 [%] and the processing is performed again, and the results are graphed, the results are shown in FIGS. 10 (a), (b) and (c). In this case, from the displayed graph, the manner in which the environmental load is reduced can be immediately known from the skin.

Particularly, the effect of reducing SOx and NOx is great.
It can be seen that the environmental load of the glass is reduced by half by recycling 100%.

This evaluation method has a great effect not only on the manufacturer but also on the entire social system, such as changing the recycling rate and quantifying the load reduction of the household electrical appliance waste treatment system. .

(Characteristics of Environmental Load Evaluating Apparatus of the Present Invention) The environmental load evaluating apparatus of the present invention is characterized by an input section in a raw material procurement stage. FIG. 13 is a diagram for explaining the difference between the conventional case and the present invention regarding the processing procedure when obtaining the environmental load in the raw material procurement stage.

Conventionally, a part name, a material name, a quantity, and a unit to be input to the input unit 21 are checked. So far,
It can be done to some extent by product developers. next,
Examine the material code in the input-output table corresponding to each material. This input-output table has a huge list of material codes, from which you must find the material code that is most suitable for the material of the part, but the input-output table is specific to the input-output table. This is a very difficult task for designers who are used to JIS symbols and abbreviations because they are classified according to unique rules. In addition, there are several possibilities, and in many cases it is difficult to know which one to apply, and there are some that cannot be understood without consulting the Ministry of International Trade and Industry, so if you want to enter them correctly, select a material code in this input-output table. At the stage, the operator takes an enormous amount of time.
Actually, when we selected the material code of the input-output table for all the materials of all the parts of the air conditioner, it took about 20 hours for all the inputs.

On the other hand, in the case of the present invention, the worker is required
What is necessary is just to input in the form of the S symbol or the abbreviation. After that, the input unit 21 automatically converts the JIS symbol or the like into the most suitable material code of the input-output table using the conversion table described later. It will be greatly shortened. Therefore, even in the case of the above-described air conditioner, since the work time for inputting the material code is reduced, the work time of the entire LCA analysis is reduced to about one-fourth of the conventional one, that is, about five hours. Therefore, an operator can easily analyze various products, and can perform environmentally friendly product development by comparing and examining the products.

FIG. 14 shows the input unit 21 of the environmental load evaluation device.
2 shows an example of a functional configuration. As shown in FIG. 14, the input unit 21 includes six input units 21a to 21a corresponding to the six stages of the product life cycle as shown in FIG.
21f. Here, a raw material procurement stage input unit 21a for the life stage S1 of the raw material procurement stage in FIG. 1 is shown.

The raw material procurement stage input section 21a mainly comprises a component selection section 101, a material input section 102, and a usage input section 103. The material input unit 102 further includes an input switching unit 111, a JIS symbol input unit 112, a material code input unit 113, a JIS symbol conversion unit 114, and a conversion table 115.

The raw material procurement stage input section 21a allows the operator of the present apparatus to select a product or part, input a material of the selected part, input a used amount of the material, and the like.

The component selection section 101 is for allowing an operator to select or input a product or component.
From the material input unit 102, the material of the part can be input by the JIS symbol or the material code of the input-output table in accordance with the operation of the operator of the present apparatus. That is, the input switching unit 111 switches to one of the JIS symbol input unit 112 and the material code input unit 113 based on an instruction from the operator. JIS symbol input unit 1
The JIS symbol of the material input from 12 is converted into a material code of an input-output table by referring to a conversion table 115 by a JIS symbol conversion unit 114 and passed to a processing unit 22. Further, the material code of the input-output table of the material input from the material code input unit 113 is passed to the processing unit 22 as it is.

[0098] The used amount input section 103 is for allowing the operator to input the used amount of each material.

Raw material procurement stage input section 21a as described above
FIG. 15 shows an example of a hardware configuration of an environment evaluation device for realizing each of the functional units.

Reference numeral 26 in FIG. 15 denotes a CPU. This CP
The bus line 27 to which the U26 is connected includes a display device 28 such as a monitor, an output device 29 such as a printer, an input device 30 such as a keyboard and a mouse, a RAM 31, a main memory 32 for storing a control program, and a file storage memory 3.
3 are connected.

The file storage memory 33 includes an input / output screen storage unit 34 for storing input / output screen forms, a material input amount storage unit 35 for storing material input amounts for each of the stages S1 to S6, a material master 36, The emission intensity storage unit 38 for storing the emission intensity unit file 37 related to the above, the arithmetic expression storage unit 39 for storing the environmental load arithmetic expression, and the JIS symbol of the material input from the material input screen in the raw material procurement stage. Sometimes, a conversion table (JIS symbol conversion table) 4 for converting it into a material code in the input-output table
It consists of 0. Further, the RAM 31 stores the memory 3
It is used to temporarily store image data for display and numerical data for processing, in addition to the control program called from 2, 33.

The input / output screen storage unit 34 has an entire menu screen (FIG. 16) displayed as an initial screen when the program is started. This whole menu screen 41
Has switches indicated by reference numerals 42 to 57 in FIG. 16, and these switches 42 to 57 are arranged so as to be easily recognized by an operator as shown in FIG.

Among these switches 42 to 57, a raw material procurement stage input switch 45 and a production stage input switch 4
6. The distribution stage input switch 47, the use stage input switch 48, the disposal stage input switch 49, and the recycle stage input switch 50 correspond to the six life stages S1 to S6, which classify the life cycle of the product. When these switches are pressed, the material input screen in the corresponding stage is called up and displayed on the display device 28.

On the other hand, the material input amount storage unit 35 stores the material input amounts input through the overall menu screen 41 and the input screens corresponding to the respective stages S1 to S6 in the environmental load arithmetic expression storage unit 39. Stored corresponding to the environmental load calculation formula. Specifically, it is stored in a format similar to the calculation forms shown in FIGS. Here, the term “material” is a broad term that includes not only raw materials such as iron and aluminum used for a certain product, but also the amount of energy such as electric power required for manufacturing and transporting the product. We use in meaning.

On the other hand, the material master 36 stored in the emission unit storage section 35 stores a material name (a material name and a material code defined in the input-output table) for which the emission unit is determined in advance. I do. The material master 35 is
In order to facilitate the search, it has a major structure, a middle class, a material name and a hierarchical structure, and is configured so that materials can be sequentially selected, narrowed down and determined. The emission unit file 37 stores the emission unit, that is, the emission amount of the environmental load factor per unit of material, in association with the material name.

[0106] The emission basic units to be used are CO2, SOx, NO obtained by estimating the input amounts of six fossil fuels from the domestic input-output table (here, integrated 407 classifications).
BOD (Biochemical Oxygen Demand), which is obtained from the industrial survey statistics of Japan and the statistical data of the water quality survey by industry, based on the input-output table classification, and C
It may be related to OD (chemical oxygen demand). In this embodiment, the emission unit is determined based on domestic statistical data, but may be determined from the same statistical data according to the country in which the analysis is performed. Alternatively, they may be held as national databases and selected.

On the other hand, the environmental load arithmetic expression storage unit 39 stores an environmental load arithmetic expression modeled for obtaining the emission amount of the environmental load factor in each of the stages S1 to S6. That is, this environmental load calculation formula is used to calculate the amount of environmental load factor emission from the input amount of each material stored in the input material storage unit 35 and the emission unit corresponding to the material. , Each life stage S1
It is modeled corresponding to S6.

Hereinafter, "model A" will be specifically described as an example of a product to be analyzed.

First, when a program start command is input from, for example, the input device 30, the CPU 26 starts the control program and displays the entire menu screen shown in FIG.

On the whole menu screen 41, first, a product name is input. If the model is already registered,
A pull-down menu can be selected from the already-introduced product selection switch 42, but when registering a new product, a new product registration switch 43 is pressed, and then inputting is performed. In this embodiment, a product name “model A” is input.

Next, switches corresponding to the respective stages S1 to S6 of the life cycle of this product, that is, a raw material procurement stage switch 45, a production stage switch 46, a distribution stage switch 47, a use stage switch 48, a disposal stage switch 49, By selecting and pressing any one of the recycle stage switches 50, each stage is turned on.

Here, only the input in the raw material procurement stage S1 according to the gist of the present invention will be described.

First, when the raw material procurement stage input switch 45 is pressed on the entire menu screen 41, a component input screen 59 shown in FIG. 17 is displayed. On this part input screen 59, the part name, material name, and usage amount of the constituent materials used for one product to be evaluated are entered in the text boxes on the display screen 59.

Here, the input method of the component name is a unit name, a component name and a two-layer hierarchical structure, for example, according to the assembly configuration of the display product displayed on the display window 60 laid out on the screen 59. It is selectable. Corresponding to the calculation of the environmental load factor, the results can be displayed by unit name. The unit name and the part name selected from the assembly configuration of the product displayed on the display window 60 are displayed in text and boxes 62 and 63, respectively. Or you may input directly here.

The material name can be entered by selecting and pressing one of the material code search switch 61a and the JIS symbol input switch 62a provided in the display window 61 laid out on the screen 59. It is also possible to select and determine the material name on the basis of JIS, or to input the material name using a JIS symbol or JIS name.

When the material code search switch 61a is selected and pressed, the display window 61 displays the material classification corresponding to the material master 36 such that the material classification is large, medium, and small. The names (names defined in the input-output table and corresponding to the material codes on a one-to-one basis) and the hierarchical structure are displayed, and the materials can be selected and narrowed down in order. The material name selected here is displayed in the text box 64.

When the JIS symbol input switch 62a is selected and pressed, a material classification corresponding to the JIS symbol classification is displayed on the display window, and the material name can be selected from among them. The JIS symbol of the material, the JIS name, and the abbreviation thereof can also be input.

For example, after selecting the unit "unit A" and the part "part A" of the product "model A", the user selects the JIS symbol input switch 62a and inputs the material name of the "part A". Will be explained. The material of “part A” is “SUH309-CP” in JIS code and JI
It is called "heat-resistant steel plate" in the S name. In the input-output table,
Metals are broadly classified into "hot rolled steel", "steel pipe", "cold finished steel", "plated steel", "cast and forged steel", "cast iron and forged products (non-ferrous metals)". It is very difficult to find out where "heat-resistant steel sheets" are located. That is, it is very difficult to select the material code search switch 61a and sequentially select the material codes of the large classification, the middle classification, and the small classification in the input-output table to determine the material name as in the related art. However, if the JIS symbol input switch 61b is selected, this problem can be solved. That is, the operator simply enters “SUH309” in text box 64.
-CP ”or its JIS name“ heat-resistant steel sheet ”
Can be input using an input device such as a keyboard.

After that, the usage amount of the material is input into a predetermined text box, and the registration switch 66 is pressed.

When the registration switch 66 is pressed, first,
If there is a JIS symbol-inputted material name, it is converted to a material code in the input-output table by referring to the conversion table stored in the table storage unit 40. That is,
The conversion table searches for a material code in the input-output table corresponding to the input JIS symbol or JIS name.

FIGS. 19 to 35 show specific examples of the metal conversion table. From such conversion tables, the JIS symbol conversion unit 114 (JIS symbol conversion unit 114) is used.
CPU2 that executes a program for realizing the functions of
6) is to search for a material code in the input-output table corresponding to "SUH-CP" or its JIS name "heat-resistant steel plate". From the conversion table shown in FIG. 26, “SUH-CP” is classified into a large category “cold finish steel” and a middle category “cold finish steel”, and a small category “special steel” (material code “26023011303”). It can be seen that it is. That is, “SUH-CP” is converted to “special steel” (material code “26023011303”).

Thereafter, the specifications entered on the screen 59 including the converted material code are automatically added as one record in the material input storage unit 35.

After the specification of all the components of the product “model A” is completed, the CPU 26 performs the following calculation by performing a predetermined operation.

That is, first, an emission unit for each material is called from the emission unit file 37 associated with the material master 36. Then, the input amount for each material and the corresponding emission unit are substituted into the corresponding environmental load calculation formula called from the environmental load formula storage unit 39. Thus, the emission amount of the environmental load factor is obtained for each material. That is, the same calculation as that described with reference to FIG. 4 is performed. This calculation is repeated the number of times corresponding to the input material. Finally, the emission amounts of the environmental load factors for each material are totaled, and the total emission amount of each environmental load factor in this raw material procurement stage is output. You.

(Conversion Table) As described above, in the environmental load evaluation apparatus of the present invention, the conversion table 11
5, the JI of each material input by the operator
By converting the S symbol or JIS name into the input-output table material code, the operator can spend the most time investigating the input-output table material code corresponding to the JIS symbol for each material. Was.

Next, the conversion table will be described. The conversion table is created according to the basic conversion rules shown in FIG. The procedure for creating the conversion table will be described with reference to FIG. 18 taking the case of metal as an example.

(Steps S101 to S102)
In the case of metals, the major categories in the input-output table are "hot rolled steel", "steel pipe", "cold finish steel", "plated steel",
Since it is divided into "cast and forged steel" and "non-ferrous metal", the letters that deserve it are given priority. Among these, there is a priority, for example, even for cold rolling, if plating,
Enter the plating category. First, in the JIS symbol for metal,
The most characteristic characters are "SC" and "S
F "," FC "," A "," M "," N "," T ",
"V", "Z", "CG", "CZ", "SE", "S
G "," SP "," SW ", and" SZ "were selected, and they were classified into their respective major categories.

(Steps S103 to S104)
In addition to those classified in step S102, those having the characters “C (cold)” and “W (line)” in the middle and those ending with “M (polished steel)” are classified into the large classification “cold”. Finished steel ”is given priority.

(Steps S105 to S106)
Except for those classified up to step S104, those having the letter "T (pipe)" in the middle fall into the large classification "steel pipe".

(Step S107) Step S106
Until then, the remainder that was not classified anywhere is a major category "hot rolled steel".

(Steps S108 to S109)
In step S107, among the items classified into the large category “hot-rolled steel”, “SK”, “SUS”, and “S
Those that are “UH” are classified into the middle category “special steel materials”.

(Steps S110 to S111)
In step S107, among those classified into the large category "hot rolled steel", those other than those classified into the middle category "special steel" in step S109, "Mn" in the middle,
Those with the characters “N”, “NC”, “CM”, and “Cr” are also classified into the middle class “special steel materials”.

(Step S112) Step S107
In the major classification "hot rolled steel",
In Steps S109 and S111, the remainder not classified into any of the middle classes becomes the middle class “normal steel”.

For example, the JIS symbol "SAPH310"
In the case of, since the classification condition to the large classification up to step S105 does not apply, in step S107, it is classified into the large classification “hot-rolled steel”, and also the classification condition of the middle classification from step S108 to step S111 Since it does not apply, in step S112, the middle classification "ordinary steel"
It turns out that it becomes.

In the case of the JIS symbol "STB340", there is a letter T in the middle, so that the classification condition of the large classification in step S105 is satisfied, and in step S106,
It turns out that it becomes a big classification "steel pipe".

Further, in the case of "SGCC" in the JIS symbol,
Since the head is "SG", the classification condition of the large classification in step S101 is satisfied, and in step S102, the classification is "large plated steel". Furthermore, this JIS symbol includes
There is a letter "C" in the middle, which is the condition of the large classification given in step S103, but since "plating" has priority over "cold finish", it is classified as "plated steel". It is.

According to the above rules, conversion tables as shown in FIGS. 19 to 35 can be created for metals.

From the notation of the metal material used in the product (for example, “SPCC” or “SWGD”), it is necessary to know what kind of manufacturing method it is manufactured and what the composition is. JI unless you are an expert in metal
In many cases, you need to review and re-examine the data such as S. Even if a worker is familiar with metals, for example, home appliances are now used in all fields, from metals to ceramics and plastics, and few workers are familiar with everything. Therefore, as in the present invention, if there is a system for automatically searching the conversion table for the material code of the input-output table used in the processing unit 22 simply by inputting the JIS symbol or abbreviation of the material, as is known in the field of materials, This makes it possible for even an unskilled worker to carry out LCA analysis extremely easily, thus making it possible to use LCA widely in the development of products that reduce environmental load.

As described above, according to the above embodiment, LCA analysis of a product can be performed easily and easily.
LCA analysis can be easily used even in home electric appliances and the like that need to develop products in a short period of time.

The method of the present invention described in the embodiment of the present invention can be executed by a computer by using a magnetic disk (floppy (registered trademark) disk, hard disk, or the like) or an optical disk (CD-RO).
M, DVD, etc.) and a storage medium such as a semiconductor memory.

The present invention is not limited to the above-described embodiment, and can be variously modified in the practical stage without departing from the gist thereof. Furthermore, the above embodiments include inventions at various stages, and various inventions can be extracted by appropriate combinations of a plurality of disclosed configuration requirements. For example, even if some components are deleted from all the components shown in the embodiment, (at least one of) the problems described in the column of the problem to be solved by the invention can be solved, and the effect of the invention can be solved. If at least one of the effects described in (1) is obtained, a configuration from which this component is deleted can be extracted as an invention.

[0142]

As described above, according to the present invention,
When evaluating the environmental load of a product, the input operation of the material information of the product at the raw material procurement stage can be performed quickly and easily.

[Brief description of the drawings]

FIG. 1 is a processing flowchart for explaining the overall configuration of a product life cycle and input data items.

FIG. 2 is a block diagram showing a schematic configuration of an environmental load evaluation device according to the embodiment of the present invention.

FIG. 3 is a model flow chart of a disposal and recycling process.

FIG. 4 is a diagram showing a calculation format in a raw material procurement stage.

FIG. 5 is a diagram showing a calculation format in a manufacturing stage.

FIG. 6 is a diagram showing a calculation format at a distribution stage.

FIG. 7 is a diagram showing a calculation format at a use stage.

FIG. 8 is a diagram showing a calculation format at a discarding stage.

FIG. 9 is a diagram showing a calculation format in a recycling stage.

FIGS. 10A to 10C are diagrams illustrating graph display examples as simulation results when the recycling rate is changed.

FIGS. 11 (a) and (b) show color T analyzed by LCA.
The figure which shows embodiment of the calculation result in V.

FIGS. 12A to 12C are pie chart display examples showing CO ₂ , SO _{x, and} NO _x emission ratios created from the results of LCA analysis.

FIG. 13 is a view for explaining a difference between a conventional case and the present invention in a processing procedure for obtaining an environmental load in a raw material procurement stage.

FIG. 14 is a diagram showing a functional configuration example of an input unit of the environmental load evaluation device.

FIG. 15 is a diagram showing an example of a hardware configuration of an environment evaluation device for realizing each functional unit of a raw material procurement stage input unit.

FIG. 16 is a diagram showing an example of an entire menu screen displayed as an initial screen when a program is started.

FIG. 17 is a diagram showing an example of a component input screen for inputting a material, a used amount, or an input amount of each component in a raw material procurement stage.

FIG. 18 is a view for explaining basic rules for creating a conversion table.

FIG. 19 is a diagram showing a specific example of a conversion table for metal.

FIG. 20 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 21 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 22 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 23 is a diagram showing a specific example of a conversion table for metal.

FIG. 24 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 25 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 26 is a diagram showing a specific example of a conversion table for metal.

FIG. 27 is a diagram showing a specific example of a conversion table for metal.

FIG. 28 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 29 is a diagram showing a specific example of a conversion table for metal.

FIG. 30 is a diagram showing a specific example of a conversion table for metal.

FIG. 31 is a diagram showing a specific example of a conversion table for metal.

FIG. 32 is a diagram showing a specific example of a conversion table for metal.

FIG. 33 is a diagram showing a specific example of a conversion table in the case of metal.

FIG. 34 is a view showing a specific example of a conversion table in the case of metal.

FIG. 35 is a diagram showing a specific example of a conversion table for metal.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 21 ... Input part 21a ... Raw material procurement stage input part 22 ... Processing part 23 ... Output part 24 ... External storage device 101 ... Component selection part 102 ... Material input part 103 ... Usage amount input part 111 ... Input switching part 112 ... JIS symbol Input unit 113: Material code input unit 114: JIS symbol conversion unit 115: Conversion table

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yoshinori Kobayashi F-term (reference) 4D004 AA46 DA16 5B049 CC00 in Toshiba Yokohama Office, 8 Shinsugita-cho, Isogo-ku, Yokohama-shi, Kanagawa

Claims (7)

[Claims] 1. The product life cycle is divided into raw material procurement, manufacturing, distribution, use, disposal, and recycling, and emission units of environmental load factors generated in each stage are provided in advance. An environmental load evaluation method for obtaining the environmental load of the product by multiplying the amount of use or the amount of input by using the amount of input or the amount of input. Calculated from the input-output table, it is stored in advance in association with the material identification information defined in the input-output table, and the stored emission unit for each material is multiplied by the used amount of the input material of the product. Determine the environmental load of the product at the raw material procurement stage by matching, and when the input material is represented by standard material identification information, Environmental load evaluation method characterized by after converting the material identification information defined material identification information of the quasi-standard in the input-output table, we obtain the environmental load of the product. 2. The material identification information of the standard created by applying the material identification information of the standard to the classification of the material identification information defined in the input-output table and the information defined in the input-output table. A correspondence table corresponding to the material identification information is stored in advance, and using this correspondence table, the material identification information of the standard is converted into the material identification information defined in the input-output table. The environmental load evaluation method according to claim 1. 3. The product life cycle is divided into raw material procurement, production, distribution, use, disposal, and recycling, and emission units of environmental load factors generated in each stage are provided in advance, and these are included in each product. An environmental load evaluation device for obtaining the environmental load of the product by multiplying the amount of the input or the amount of the input by the amount of the input or the amount of the input. A storage unit that calculates in advance from the input-output table and stores it in association with the material identification information defined in the input-output table; and at least the material identification information of the product and the amount of the material used in the raw material procurement stage. Or input means for inputting the amount of input, and when inputting the material identification information, as the type, material identification information of standard Selecting means for selecting any one of the material identification information defined in the table; and when the material identification information is input with the material identification information of the standard by the input means, the material of the standard Conversion means for converting identification information into material identification information defined in the input-output table; and an emission unit stored in correspondence with the material identification information defined in the input-output table, the input material of the product. Processing means for obtaining an environmental load of the product at the raw material procurement stage by multiplying the amount of the raw material by the amount of use of the raw material. 4. The product life cycle is divided into raw material procurement, production, distribution, use, disposal, and recycling, and an emission factor of an environmental load factor generated in each stage is provided in advance. An environmental load evaluation device for obtaining the environmental load of the product by multiplying the amount of the input or the amount of the input by the amount of the input or the amount of the input. Storage means for calculating in advance from the linkage table and storing it in association with the material identification information defined in the input-output table, and at least the material identification information of the standard of the product and the material in the raw material procurement stage Input means for inputting the used amount or input amount of the material, and material identification information of the standard entered by the input means is defined in the input-output table. Conversion means for converting to defined material identification information, by multiplying the emission unit stored corresponding to the material identification information defined in the input-output table with the amount of input material used for the product Processing means for determining an environmental load of the product at the raw material procurement stage. 5. The conversion device according to claim 1, wherein the conversion unit applies the material identification information of the standard to the classification of the material identification information defined in the input-output table. A correspondence table with the material identification information defined in the table is stored in advance, and using this correspondence table, the material identification information of the standard is converted into the material identification information defined in the input-output table. The environmental load evaluation device according to claim 3 or 4, wherein: 6. The product life cycle is divided into raw material procurement, manufacturing, distribution, use, disposal, and recycling, and the emission unit of the environmental load factor generated at each stage is used or input for each product. A program product for causing a computer to execute a process for determining the environmental load of the product by multiplying the product identification information of at least the product at the raw material procurement stage, and the amount of use or input of the material. And when inputting the material identification information, select one of the type of the material identification information of the standard and the material identification information defined in the input-output table as the type. When the material identification information is input with the material identification information of the standard, the material identification information of the standard is defined in the input-output table. Multiplying the amount of input material used for the product by a process for converting into defined material identification information and an emission unit stored corresponding to the material identification information defined in the input-output table A process for determining the environmental load of the product at the raw material procurement stage. 7. The product life cycle is divided into raw material procurement, manufacturing, distribution, use, disposal, and recycling, and the emission unit of environmental load factor generated in each stage is used or input for each product. A computer-readable recording medium that records a program for causing a computer to execute a process of determining an environmental load of the product by multiplying the product by at least the material identification information of the product at the raw material procurement stage, A process for inputting the amount of use or input of the material, and when inputting the material identification information, as a type, between the material identification information of the standard and the material identification information defined in the input-output table. A process for selecting any one of the following: and when the material identification information is input using the standard material identification information, A process for converting the material identification information of the quasi-standard into the material identification information defined in the input-output table, and the emission intensity stored corresponding to the material identification information defined in the input-output table. A process for obtaining the environmental load of the product at the raw material procurement stage by multiplying the amount of the input material of the product by the amount used, and a program for causing a computer to execute the process.