Information Sources

For Chile, it is possible to obtain industrial data on employment, raw material and energy consumption, and physical production from the Annual National Industrial Survey (ENIA). For this study, variables including identification information, the International Standard Industrial Classification (ISIC) economic activity code, region, fuel consumption, fuel measurement units, fuel expenditure, and working days (Table A2 in Appendix) were used. In particular, we used the 2011 survey because it was the latest available at the time of the study’s termination (at the beginning of 2015).

To estimate the energy used by each industrial source, we used the data from ENIA on the quantity of each consumed fuel, as well as the fuel density and heating values obtained from the National Energy Balance from the Ministry of Energy and the US Environmental Protection Agency (EPA 2009). However, the ENIA survey does not directly identify which industry sources have thermal power greater than 50 MW; this can be inferred only indirectly by annual fuel consumption. Therefore, the following descriptive analysis presents the behavior of all industrial sources (independent of MW of thermal power) that are included in the ENIA survey (3,223 industrial sources).

The following industry sectors consume high quantities of coal: the metallurgical industry, with 66 percent of total fuel consumption (129,712 million tons per year); the nonmetallic minerals industry, with 20 percent of total consumption (39,307 million tons year); and the food industry, with 13 percent of total consumption (25,549 million tons per year).

The largest industry sector that mainly consumes fuel oil and diesel is the food industry, with 53 percent of the total (650 million tons per year); this is followed by the paper industry, with 22 percent (270 million tons per year), and the nonmetallic minerals industry, with 5 percent (61 million tons per year).

The industry sector that consumes the most gasoline is the food industry, with 40 percent of the total coal consumption (7,429 tons per year); this is followed by the metal-mechanical industry, with 12 percent (2,229 tons year), and the metal products industry, with 10 percent (1,857 tons per year).

The highest-consuming liquefied petroleum gas (LPG) industry sectors are the food industry, with 39 percent (41,509 tons per year), followed by the chemical industry, with 16 percent (17,029 tons per year), and the paper industry, with 14 percent (14,901 tons per year).

Natural gas is primarily consumed in the chemical industry, with a consumption of 34 percent (175,174 tons per year); this is followed by the food industry, with 19 percent (98,892 tons per year), and the paper industry, with 19 percent (98,892 tons per year).

The largest biomass consumer in the industry sector is the paper industry, with 64 percent (726,980 million tons per year); this is followed by the wood industry, with 22 percent (249,900 million tons per year), and the food industry, with 14 percent (159,027 million tons per year).

Estimation of CO₂ Emissions

The following fossil-fuel sources were considered in order to evaluate the effect of applying a CO₂ tax on industrial sources; coal, diesel oil, fuel oil, natural gas, and biomass. Other fuels, such as gasoline and kerosene, are not primarily used in the production processes of industries, whereas LPG is mainly used for room and office heating. For those industrial sources that consume more than one fuel, they were divided into a source for each fuel (coal, biomass, petroleum No. 6, petroleum No. 2, and natural gas); thus, the research has information from 3,223 sources. In the baseline scenario, all these sources emit a total of 5,198,826 tons of CO₂.

To evaluate a potential change of fuel in case of a CO₂ tax, it is necessary to know the quantity of fuel required for each industrial source to generate the same quantity of energy (BTU). If the payable tax amount under the original fuel for an industrial source is greater than the sum of the annualized cost of technology investments and the increase of spending associated with the new fuel, the industrial source should then reduce its emissions.

To estimate the quantities of CO₂ emitted by each industrial source, the consumed quantities of energy must be multiplied by the factors of CO₂ emissions according to the type of fuel. These data are obtained from “IPCC Guidelines Reference Eggleston, Buendia, Miwa, Ngara and Tanabe2006 for the National Greenhouse Gases Inventories” (Table 1).

Table 1: CO₂ emission factors per fuels.

Source: IPCC Reference Eggleston, Buendia, Miwa, Ngara and Tanabe2006.

It is important to note that the CO₂ emission factor for biomass is zero because trees capture CO₂ from the atmosphere during growth; then, in the process of burning the same quantity of wood, the CO₂ captured during the growth phase is released. Although this course has been questioned because the recapture of vegetation may vary from years to centuries, it is valid to assume zero emissions in this study because the tax in Chile excludes emission sources that use biomass as fuel.

Technology Options

Of the industrial sources to be analyzed, 303 consume solid fuels (225 consume biomass and 78 consume coal), 2,114 consume liquid fuels (1,403 consume petroleum No. 2 and 711 consume petroleum No. 6), and 806 consume natural gas.

The technological requirements that are necessary to change the fuel currently used in the production processes from industrial sources are presented in Table 2. Sources that consume liquid fuels will need to change to dual burners, which operate on gas and petroleum. Conversely, the solid fuel sources that want to use liquid or gaseous fuels will require a complete change of equipment, because the fuel supply to the boiler and in the area in which the fuel is burned differs.

Table 2: Technological requirements.

Source: Own elaboration from Mechanical Engineering Department, University of Concepción.

However, the ENIA survey does not specify the technical characteristics of the combustion equipment of the sources; in particular, it does not include thermal powers in MW (PotMW) that are relevant to determining the equipment cost. Then, and based on the Industrial Emissions Inventory from Metropolitan Concepción (UDT-PROTERM 2011), it was possible to obtain a sample from industrial sources that included information on fuel consumption and boiler power; this information was used to estimate functions to simulate the boiler power for each industrial source that was included in the ENIA survey (see Table A1 in Appendix). The estimated functions, the standard errors of the coefficients, and R² are as follows:

(1) $\begin{array}{c}{\text{PotMW}}_{\text{Biomass}}=0.0000881+5.58*\text{Biomass Consumption}\left(\text{Kg}\right)R^2=0.61\\ \left(0.0000677\right)\left(1.70\right)\end{array}$

(2) $\begin{array}{c}{\text{PotMW}}_{\mathrm{Coal}}=0.0014727*\text{Coal consumption}\left(\mathrm{Kg}\right)R^2=0.66\\ \left(0.0002488\right)\end{array}$

(3) $\begin{array}{c}{\text{PotMW}}_{\mathrm{petroleum}/\mathrm{gas}}=0.0036547*\text{Petroleum\hspace{0.17em}or\hspace{0.17em}gas\hspace{0.17em}consumption\hspace{0.17em}}\left(m^3\right){\text{R}}^{\text{2}}=0.70\\ \left(0.0004095\right)\end{array}$

The Economic Costs of Technological Options

To perform a comparative analysis of different alternatives for the industrial sources once a CO₂ tax on emissions is applied, it is necessary to know the data regarding the energy consumed by the different sources and the power in MW of each piece of combustion equipment, the quantity of technological equipment used in each source,Footnote ⁵ the value of the new combustion equipment, the fuel prices per power unit, and the number of tons of CO₂ emitted from the fuel being evaluated.

The fuel prices were obtained from the ENIA survey as the average value per MMBTU (one million BTU) paid by sources in each region of Chile. In the regions without fuel price information, the average price of the nearest regions is reported. Table 3 contains price information for each type of fuel.

Table 3: Fuel price US$/MMBTU for 2011.

Source: Own elaboration from ENIA 2011.

Because alternative fuel switching is associated with a change in boilers or burners, it is necessary to formulate an annualized cost function for each of the source’s options for change. It was possible to know the price of burners and boilers that are required for fuel change from combustion equipment quotes. Then, the annualized investment cost of this equipment was related to the MW thermal power to estimate the statistical functions that allow the extrapolation of the annualized cost for all industrial sources available in the ENIA data:Footnote ⁶

(4) $\begin{array}{c}{\text{CT\hspace{0.17em}Boiler}}_{\mathrm{pet}/\mathrm{gas}}=236886+1421722*\text{PotMW}+65381*{\text{PotMW}}^2{\text{R}}^2=1.00\\ \left(48935\right)\left(69719\right)\left(910\right)\end{array}$

(5) $\begin{array}{c}{\text{CT\hspace{0.17em}Burner}}_{\text{pet}/\text{gas}}=199077+131720*\text{PotMW}{\text{R}}^{\text{2}}=0.91\\ \left(43860\right)\left(9844\right)\end{array}$

(6) $\begin{array}{c}{\text{CT\hspace{0.17em}Boiler}}_{\mathrm{ccoal}}=(513041*{\text{PotMW}}^2-631*{\text{PotMW}}^3+0.2*{\text{PotMW}}^4)*0.86\\ \left(46054\right)\left(75\right)\left(0.25\right)\\ +(1-0.86)*112000000*\text{PotMW}{\text{R}}^{\text{2}}=1.00\\ \left(7693338\right)\end{array}$

(7) $\begin{array}{c}{\text{CT\hspace{0.17em}Boiler}}_{\mathrm{biomass}}=20200000*\text{PotMW}{\text{R}}^{\text{2}}=1.00\\ \left(4937990\right)\end{array}$

These functions correspond to the annualized investment in boilers and burners; however, they do not cover the additional costs of installation, which correspond to 20 percent of the cost of the boiler (Reference EscobarEscobar 2013).

Because the CO₂ tax paid by industrial sources will depend on the tons of CO₂ emitted per year, it is necessary to know the annual cost of the fuels used and the annualized price of the boilers and burners to economically valuate the best option to address this tax. An equipment life of twenty years was considered to obtain the equivalent annual cost of the technological equipment; this horizon is used in industrial boiler projects that are admitted to the Environmental Assessment in Chile.Footnote ⁷

Comparison of Alternatives Based on Cost Indicators

To address the existence of a CO₂ tax, it was considered that each source could maintain its fuel consumption and could switch to any of the other types of fuels. Thus, a comparison table was created in which the current scenario was present with no investment in technological equipment but considers the cost of the tax for annual tons of CO₂ emitted by the fuel used. Furthermore, four additional scenarios for each fuel were generated; they reflected the annualized cost of the acquisition of technological equipment to create a change of fuel, the installation cost of such equipment, the annual differential fuel cost to maintain the fuel energy equivalence, and the cost per ton of CO₂ emissions through the use of the new fuel.

The analysis of the quantity of industrial sources that could decide to change their use of fuel were first restricted according to the availability of certain fuels. Thus, in the case of biomass availability, this number was limited to the regions of Arica-Parinacota, Tarapacá, Antofagasta, and Atacama, according to information from the Ministry of Agriculture.Footnote ⁸ At the same time, natural gas was also limited because not all regions have pipeline capacity that enables the supply of this fuel (information from the National Energy Commission).Footnote ⁹

Then, total costs were compared for each of the alternatives that could opt for industrial sources. Moreover, different adjustment costs were applied to simulate the initial equilibrium because certain sources, in the absence of taxes, equally chose to switch fuel.Footnote ¹⁰ These sources were estimated, and adjustment costs were added that allow for replication of the base situation.

Finally, an analysis of scenarios was performed; it considers different error rates in estimating the potential adjustment costs by undercutting the estimation of costs associated with changes in the combustion equipment in the sources.

For a better understanding of the methodology used in Table A3 (Appendix), twenty-five industrial sources (identified by ID) are shown as examples. This table is a sample of the total industrial sources included in the analysis. This table includes fuel consumption, energy used (BTU), boiler power (MW), number of boilers, original CO₂ emissions, and the annualized cost indicator (US$) for each alternative for fuel change under the same energy requirement. Finally, from the lower cost indicator chosen, each fuel source is selected to determine the final emissions and CO₂ tax collections.